ThesisPDF Available

Creating a Better World: Questions, Actions and Expectations of International Students on Sustainable Development and its Education

Authors:

Abstract and Figures

Chemistry plays a key role in dealing with several of the big environmental problems of the future, but yet, chemistry education is often seen as irrelevant by students. Therefore, it is evident that ways to make chemistry education more relevant are called for. Educational experts have argued that sustainable development is a context that would bring relevance to science education, including chemistry education, as it bridges the gap between science and society. However, research on students’ perspective on the relevance of sustainable development is scarce. This thesis examines sustainable development and its education from the students’ viewpoint. This is done by seeking to answer the research problem: What do international students find relevant in sustainable development and its education? To answer this research problem, this thesis breaks down the problem into four research questions. The first research question examines what type of questions students ask about sustainable development, particularly in the area climate change. The second research question examines the kind of actions students take to make the world a better place. The third research question examines students’ expectations when applying to a non-formal educational program focused on sustainable development. The last research question examines how these expectations were met through the non-formal educational program. To address the research problem, the thesis adopted a multi-method approach, consisting of descriptive research, case studies and elements of grounded theory. The data was collected before, during and after an international youth camp, the Millennium Youth Camp held in the summers of 2010-2014. The participants of the study were 16-19 -year old students from around the world who were interested in science. The thesis consists of six interconnected studies. The first study examines the type of questions students ask about sustainable development and the second study examines the type of questions students ask about climate change, specifically. The data for these two studies were collected through an online survey from the students applying to the international youth camp. The data were analyzed using content analysis. The results indicate that students ask a variety of academic, societal and moral questions related to sustainable development. These questions cover many relevant aspects of sustainable development, and climate change specifically, and build a premise for student-centered education. In the third study, students attending the international youth camp were interviewed on the type of actions they take to make the world a better place. The data was analyzed though inductive and deductive content analysis and the results show that student actions can be categorized into three distinct groups, namely, personal responsible actions, participatory actions and future oriented actions. The fourth study used quantitative methods to address what type of expectations students have in education for sustainable development. The data was collected from students applying to the non-formal education program. The results show that in addition to wanting more knowledge on specific scientific phenomena and the nature of science, students expect to learn about societal impacts of environmental issues and discuss related moral issues. Studies four, five and six examine how the aforementioned expectations of the students can be met through non-formal education. These studies examine what type of structures and programs in the camp made the educational experience relevant for the students. The thesis concludes by asserting that students’ questions, actions and expectations can be used to make education for sustainable development more relevant in a number of ways. The thesis discusses the possibilities of (i) moving towards more student-centered learning, in which students’ questions and actions are the foundation of education, (ii) increasing relevant social and societal discussion with peers and experts, and (iii) providing students with opportunities to work on projects that address student interest. The thesis takes examples from the non-formal educational program studied and discusses how these same methods could be implemented into other similar programs or formal education.
Content may be subject to copyright.
UNIVERSITY OF HELSINKI
CREATING A BETTER WORLD
Questions, Actions and Expectations of International Students on
Sustainable Development and Its Education
Sakari Tolppanen
The Unit of Chemistry Teacher Education
Department of Chemistry
University of Helsinki
Finland
ACADEMIC DISSERTATION
To be presented, with the permission of the Faculty of Science of the University of
Helsinki, for public examination in lecture room A110, Department of Chemistry,
on 24 June 2015, at 12 noon.
Helsinki 2015
Publisher: Department of Chemistry, Faculty of Science, University of
Helsinki
Dissertations of the Unit of Chemistry Teacher Education, 6
ISSN 1799-1498
ISBN 978-951-51-1311-5 (paperback)
ISBN 978-951-51-1312-2 (PDF)
http://ethesis.helsinki.fi
Cover image: Pekka Isometsä & Sakari Tolppanen
Author’s address Department of Chemistry
P.O. Box 55
FI -00014 University of Helsinki
Finland
sakari.tolppanen@helsinki.fi
Supervisor Professor Maija Aksela
Unit of Chemistry Teacher Education
Department of Chemistry
Faculty of Mathematics and Natural Science
University of Helsinki
Finland
Reviewers Professor Brian Lewthwaite
Centre for Research & Innovation in
Sustainable Development
College of Arts & Society & Education
James Cook University
Australia
Professor Jan Lundell
Department of Chemistry
Faculty of Mathematics and Natural Science
University of Jyväskylä
Finland
Opponent Professor Ingo Eilks
Institute of Science Education
Department of Chemistry
University of Bremen
Germany
Custos Professor Markku Räsänen
Department of Chemistry
Faculty of Science
University of Helsinki
ABSTRACT
Chemistry plays a key role in dealing with several of the big environmental problems
of the future, but yet, chemistry education is often seen as irrelevant by students.
Therefore, it is evident that ways to make chemistry education more relevant are called
for. Educational experts have argued that sustainable development is a context that would
bring relevance to science education, including chemistry education, as it bridges the gap
between science and society. However, research on students’ perspective on the relevance
of sustainable development is scarce.
This thesis examines sustainable development and its education from the students’
viewpoint. This is done by seeking to answer the research problem: What do
international students find relevant in sustainable development and its education?
To answer this research problem, this thesis breaks down the problem into four
research questions. The first research question examines what type of questions students
ask about sustainable development, particularly in the area climate change. The second
research question examines the kind of actions students take to make the world a better
place. The third research question examines students expectations when applying to a
non-formal educational program focused on sustainable development. The last research
question examines how these expectations were met through the non-formal educational
program. To address the research problem, the thesis adopted a multi-method approach,
consisting of descriptive research, case studies and elements of grounded theory. The data
was collected before, during and after an international youth camp, the Millennium Youth
Camp held in the summers of 2010-2014. The participants of the study were 16-19 -year
old students from around the world who were interested in science.
The thesis consists of six interconnected studies. The first study examines the type of
questions students ask about sustainable development and the second study examines the
type of questions students ask about climate change, specifically. The data for these two
studies were collected through an online survey from the students applying to the
international youth camp. The data were analyzed using content analysis. The results
indicate that students ask a variety of academic, societal and moral questions related to
sustainable development. These questions cover many relevant aspects of sustainable
development, and climate change specifically, and build a premise for student-centered
education. In the third study, students attending the international youth camp were
interviewed on the type of actions they take to make the world a better place. The data was
analyzed though inductive and deductive content analysis and the results show that student
actions can be categorized into three distinct groups, namely, personal responsible actions,
participatory actions and future oriented actions.
The fourth study used quantitative methods to address what type of expectations
students have in education for sustainable development. The data was collected from
students applying to the non-formal education program. The results show that in addition
to wanting more knowledge on specific scientific phenomena and the nature of science,
students expect to learn about societal impacts of environmental issues and discuss related
moral issues. Studies four, five and six examine how the aforementioned expectations of
the students can be met through non-formal education. These studies examine what type of
structures and programs in the camp made the educational experience relevant for the
students.
The thesis concludes by asserting that students’ questions, actions and expectations can
be used to make education for sustainable development more relevant in a number of
ways. The thesis discusses the possibilities of (i) moving towards more student-centered
learning, in which students questions and actions are the foundation of education, (ii)
increasing relevant social and societal discussion with peers and experts, and (iii)
providing students with opportunities to work on projects that address student interest.
The thesis takes examples from the non-formal educational program studied and discusses
how these same methods could be implemented into other similar programs or formal
education.
TIIVISTELMÄ
Kemian osaaminen on keskeistä kestävän kehityksen edistämiseksi ja globaalien
ympäristöhaasteiden ratkaisemiseksi ja ennaltaehkäisemiseksi. Opiskelijat eivät
kuitenkaan usein ymmärrä kemian merkityksellisyyttä kestävän kehityksen ja
tulevaisuuden hyvinvoinnin kannalta. Kestävän kehityksen edistämiseksi tarvitaankin
uusia oppilaslähtöisiä opetuksen lähestymistapoja, jossa aihetta tarkastellaan sen eri
näkökulmista globaalisti. Toistaiseksi kestävän kehityksen opetusta opiskelijoiden
näkökulmasta on kuitenkin tutkittu kemian kontekstissa vain vähän.
Tämä väitöskirjatutkimus tarkastelee kestävää kehitystä ja sen opetusta kansainvälisten
opiskelijoiden näkökulmasta. Tarkastelun tavoitteena on vastata päätutkimusongelmaan:
Mitä 1619 -vuotiaat opiskelijat pitävät merkityksellisenä kestävässä kehityksessä ja
sen opetuksessa? Ongelma on jaoteltu neljään tutkimuskysymykseen. Ensimmäinen
tutkimuskysymys tarkastelee, minkälaisia kysymyksiä nuoret opiskelijat kysyvät
kestävästä kehityksestä ja erityisesti ilmastonmuutoksesta. Toinen tutkimuskysymys
tarkastelee, minkälaisia tekoja opiskelijat tekevät parantaakseen maailmaa. Kolmas
tutkimuskysymys tarkastelee opiskelijoiden ennakko-odotuksia heidän hakiessa
kansainväliselle Millennium Youth Camp tiedeleirille, jossa pääteemana on kestävä
kehitys. Neljäs tutkimuskysymys tarkastelee, miten leiri vastasi nuorten ennakko-
odotuksiin leiristä ja sen sisällöstä. Tutkimuksessa käytettiin seuraavia menetelmiä:
kuvaileva tutkimus (engl. descriptive research), tapaustutkimus ja grounded theory.
Aineistoa kerättiin ennen kansainvälistä tiedeleiriä, leirin aikana sekä leirin jälkeen
vuosina 20102013.
Tämä väitöskirja koostuu kuudesta, toisiinsa liittyvästä tutkimuksesta. Ensimmäinen
tutkimus tarkastelee, minkälaisia kysymyksiä nuoret kysyvät kestävästä kehityksestä ja
toinen tutkimus, minkälaisia kysymyksiä nuoret kysyvät ilmastonmuutoksesta. Näiden
kahden tutkimuksen aineisto kerättiin nettikyselyllä niiltä nuorilta, jotka hakivat leirille.
Aineisto analysoitiin sisältöanalyysin menetelmin. Tulokset osoittavat, että nuorten
kysymykset liittyvät kestävän kehityksen tieteellisiin, yhteiskunnallisiin ja moraalisiin
ulottuvuuksiin. Nämä kysymykset kattavat kestävän kehityksen ja ilmastonmuutoksen
osa-alueita hyvin laajalti ja luovat perustaa sille, miten opetuksessa voitaisiin siirtyä
oppilaskeskeisempään lähestymistapaan. Kolmannessa tutkimuksessa selvitettiin
haastatteluja käyttäen, minkälaisia tekoja leirille tulleet nuoret tekevät ympäristön ja
maailman hyväksi. Aineisto analysoitiin käyttäen induktiivista ja deduktiivista
sisältöanalyysiä. Tutkimuksen tulokset osoittavat, että nuorten teot voidaan jakaa kolmeen
ryhmään: henkilökohtaiset vastuulliset teot, yhteisölliset teot ja tulevaisuuteen tähtäävät
teot.
Neljäs tutkimus käytti kvantitatiivisia menetelmiä, selvittääkseen minkälaisia
odotuksia nuorilla on kestävän kehityksen opetuksesta. Aineosto kerättiin nuorilta, jotka
olivat hakemassa kansainväliselle tiedeleirille. Tulokset osoittivat, että sen lisäksi että
nuoret haluavat lisää tietoa luonnontieteistä ja luonnontieteen luonteesta, he myös haluavat
oppia yhteiskunnallisista ulottuvuuksista ja ympäristön ongelmista. Myös näihin liittyvät
moraaliset keskustelut ovat heille tärkeitä. Tutkimukset neljä, viisi ja kuusi tutkivat, miten
näihin nuorten odotuksiin voidaan vastata selvittämällä, minkälaiset rakenteet ja ohjelmat
tekivät leireistä merkityksellisiä oppimisympäristöjä opiskelijoille.
Tutkimus tuo lisätietoa oppilaslähtöisen kestävän kehityksen opetuksen suunnittelun ja
toteutuksen tueksi. Esimerkiksi nuorten kysymykset, teot ja odotukset
ilmastonmuutokseen liittyen on tärkeä huomioida kemian opetuksessa. Kestävän
kehityksen merkityksellisessä opetuksessa olisi hyvä huomioida seuraavat tavat: (i) siirtyä
oppilaskeskeisempään opiskeluun, jossa opiskelijoiden kysymykset ja teot muodostavat
opetuksen lähtökohdan, (ii) lisätä merkityksellistä yhteiskunnallista keskustelua
opiskelijoiden kesken ja asiantuntijoiden kanssa ja (iii) antaa opiskelijoille mahdollisuus
työskennellä projekteissa, jotka vastaavat heidän omia kestävään kehitykseen liittyviä
mielenkiinnon kohteita. Väitöskirjassa esitetään myös, miten näitä leirillä tutkittuja
lähestymistapoja voitaisiin siirtää kouluopetukseen.
ACKNOWLEDGEMENTS
First and foremost, I want to thank my supervisor, Professor Maija Aksela, for
encouraging me to take a step into the unknown and start working on this thesis. Thank
you for guiding me during these first steps into the world of research and for believing in
me and giving me the support and freedom I needed to pursue my interests. Without you
this thesis would not have been possible.
I also want to say a special thank you to Professor Kirsi Tirri, who I’ve had the chance
to collaborate with on several occasions. I have learned many valuable lessons from our
collaboration. I am also very thankful for the other researchers I have had the opportunity
to work with: Dr. Veli-Matti Vesterinen, Dr. Elina Kuusisto, Jenni Vartiainen and Veli-
Matti Ikävalko, your input and insight is highly appreciated. I am also very thankful to all
my great colleagues at the Unit of Chemistry Teacher Education who have shared the joys
and burdens of this journey with me, as well as broadened my view on chemistry
education and research.
I am thankful to my custos, Professor Markku Räsänen and the Department of
Chemistry for providing the facilities to work in, as well as the financial support.
I am very grateful for the insightful comments and corrections given by the pre-
examiners, Professor Brian Lewthwaite from James Cook University, Australia, and
Professor Jan Lundell from the University of Jyväskylä, Finland. A deep bow also goes to
Chris Rynberk for proofreading my work. You have all contributed to making this thesis
more solid and reader friendly. A big thank you also goes to Professor Ingo Eilks from the
University of Bremen, Germany, for agreeing to be my opponent and to challenge my
work so that I may learn through our discussions.
I also want to thank LUMA center Finland, Technology Academy Finland, Aalto
University and The University of Helsinki and a number of companies for making the
Millennium Youth Camp possible. The camp has not only been the foundation of my
research, but has been a place where I have met great researchers, visited interesting
companies and most importantly, made life-long friends. I thank all of the Millennium
Youth Campers for not only being my “research specimen”, but for being the passionate
and inspiring people that you are. Having witnessed the drive that you have continues to
inspire me. As we say, “you may leave MyCamp, but MyCamp will never leave you”.
I thank my dad for planting a thirst for knowledge in me. Through your wisdom you
have guided me in many areas of life. I thank my mom for being the gentle, loving person
that you are. I know that I can always turn to you with all my joys and sorrows. I thank my
sister for all the great moments and conversations that we’ve shared over the years. You
have also convinced me that I am cool even though I read books. Thank you for that sweet
lie. I also thank Josh for being the brother I never had and for being so passionate about
the things you do. Your passion has caught onto me and helped me strive.
Thanks to all my friends who have reminded me that there is a world beyond books
and academia. You have brought balance to my life, and I thank you for the fact that I am
still sane and doing well. Last but not least, I thank my Heavenly Father for providing me
with all that has been mentioned, and much much more. Because of your grace, I am truly
blessed.
LIST OF ORIGINAL PUBLICATIONS
This thesis is based on the following publications:
I Tirri, Tolppanen, Aksela & Kuusisto (2012). A Cross-Cultural Study of
Gifted Students’ Scientific, Societal and Moral Questions Concerning
Science. Education Research International. 2012, 1-7.
II Tolppanen & Aksela (submitted). Towards a More Holistic Climate Change
Education Students’ Perspective.
III Vesterinen, Tolppanen & Aksela (submitted). Towards Citizenship Science
Education: What Students do to make the World a Better Place?
IV Tolppanen, Vartiainen, Ikävalko & Aksela (2015). Relevance of non-formal
Education in Science Education. In I. Eilks (Ed.), Relevant Chemistry
Education - From Theory to Practice. pp 325-344. Sense Publishing.
V Tolppanen & Tirri (2014). How an Enrichment Summer Program Is
Meeting the Expectations of Gifted Science Students: A Case Study from
Finland. International Journal of Talent Development and Creativity, 2(1),
103-115.
VI Tolppanen & Aksela (2013). Important Social and Academic Interactions in
Supporting Gifted Youth in Non-Formal Education. LUMAT. 1(3), 279-298.
The publications are referred to in the text by their roman numerals.
Author’s contributions to the publications:
I: The author was co-responsible for planning the research and collecting
and analyzing the data. The author was involved in the writing of all parts of
the article.
II, V, VI: The author was responsible for planning the research and
collecting and analyzing the data. The author was involved in the writing of
all parts of the article.
III: The author was co-responsbile for planning and setting up the research.
The author participated in analyzing the data and writing the article.
IV: The author was responsible for planning and organizing the study,
writing the theoretical framework, the section on Non-formal education for
gifted 1619 year old students and the conclusions.
ABBREVIATIONS
etc. et cetera
e.g. exempli gratia
ESD Education for Sustainable Development
NOS Nature of Science
SSI Socio-Scientific Issues
CONTENTS
1. INTRODUCTION 1
2. SUSTAINABLE DEVELOPMENT AND ITS EDUCATION 5
2.1. Sustainable Development 5
2.2. Education for Sustainable Development 6
2.2.1 Climate change education 8
3. RELEVANT EDUCATION 11
3.1. Defining Relevant Education 11
3.2. Student-Centered Education 12
3.1.1 Action competence 13
3.3. Non-Formal Education 13
3.4. Gifted Education 14
4. METHODOLOGICAL FRAMEWORK 17
4.1. Descriptive Research 17
4.2. Case Study 18
4.3. Grounded Theory 18
4.4. Mixed methods research and triangulation 19
5. DESCRIPTION OF THE STUDIES 21
5.1. Students’ Questions on Sustainable Development 21
5.1.1 Data collection and analysis 22
5.1.2 Results 23
5.1.3 Summary 24
5.2. Students’ Actions to Make the World a Better Place 24
5.2.1 Data collection and analysis 25
5.2.2 Results 25
5.2.3 Summary 26
5.3. Students’ Expectations of Non-Formal Education within a Context of
Sustainable Development 26
5.3.1 Data collection and analysis 27
5.3.2 Results 27
5.3.3 Summary 28
5.4. Non-Formal Education Meeting Students’ Needs and Expectations 28
5.4.1 Data collection and analysis 28
5.4.2 Results 30
5.4.3 Summary 31
6. VALIDITY AND RELIABILITY 33
7. DISCUSSION AND CONCLUSIONS 35
7.1. Students’ Questions on Sustainable Development 35
7.1. Students’ Actions 36
7.2.1 Action Competence 38
7.3. Students’ Expectations of Non-Formal Education 39
7.4. Meeting Students’ Needs and Expectations through Non-Formal Education 40
7.5. Implications 42
REFERENCES 45
1
1. INTRODUCTION
Chemistry plays a key role in solving many of the environmental challenges of today
and tomorrow. For instance, chemistry is important in finding ways to preserve and
replace our diminishing resources (such as oil, minerals and clean water), as well as
finding solutions to eutrophication, climate change and erosion of farmlands. However,
research conducted around the world shows that students tend to see science education,
including chemistry education, as irrelevant (Hofstein, Eilks, & Bybee, 2011; Osborne &
Dillon, 2008). Therefore, it is apparent that the goals and content of the chemistry
curriculum do not meet the needs and expectations of students (see Hofstein et al., 2011).
Researchers have suggested that this is because the chemistry curriculum is often
decontextualized from the students’ everyday lives (Aksela & Karjalainen, 2008; Hofstein
et al., 2011). Recent research has also shown that especially societal relevance is lacking
in chemistry education (Hofstein et al., 2011; Stuckey, Hofstein, Mamlok-Naaman, &
Eilks, 2013). Therefore, this thesis aims to find out how education could be made more
relevant, namely through sustainable development and non-formal education. Although
examining how to make education more relevant is by no means a new endeavor, this
thesis brings a new perspective to the discussion by focusing on the students’ perspective.
This is done by examining the following research problem:
What do international youth find relevant in sustainable development and its
education?
As this research problem is broad and complex, answering it as such is challenging.
For this reason, this thesis focuses on four research questions that add to the discussion of
the main research problem. These research questions are:
RQ1: What type of questions do students ask about sustainable
development?
RQ2: What type of actions do students take to make the world a better
place?
RQ3: What type of expectations do students have for non-formal
education with a context of sustainable development?
RQ4: How can students’ needs and expectations be met through non-
formal education?
The relationship between the research problem, the research questions and the six
studies presented in this thesis are presented in Gigure 1. However, it is important to note
that the figure is a simplification of the relationships between the research questions and
the studies. For instance, students’ questions (RQ1) give indication of the students’
educational expectations (RQ3), though a link between the two is not drawn in the figure.
Furthermore, the findings of students’ questions (RQ1) and actions (RQ2) contribute to
the discussion on how students’ expectations can be met (RQ4). In sum, all of the studies
2
and research questions interlink with each other. However, drawing all of these
connections into the figure would only make it hard to read.
Figure 1. A simplified structure on how the research problem, research questions and
the studies are connected.
To answer the first research question, this thesis includes two studies on the topic.
Study I gives a broad outline on what kind of questions students ask about sustainable
development in a science context. Study II then goes deeper into this topic by analyzing
what type of questions students ask about climate change in specific. The significance of
these two studies in relation to student-centered education (e.g. Jonassen, 2000) will be
discussed. The second research question is answered through Study III, in which students
are interviewed on the kind of actions they take in order to make the world a better place.
The results of this study add to the discussion of action competence (see Hofstein et al.,
2011), an important aspect of relevant Education for Sustainable Development (ESD).
Study IV (a) aims to answer the third research question by studying what type of
expectations students have before attending a non-formal educational program. Students’
expectations go beyond academic expectations, and therefore, in order to provide relevant
education for the students, non-academic aspects should be acknowledged in education, as
will be discussed further in this thesis. The final research question is answered with the
help of three studies presented in this thesis. Study V discusses the relevance and non-
formal education in general. Study IV (b) and Study VI then discuss how students’
expectations can be met through relevant non-formal science education. In the general
conclusions, the findings of the six studies are linked to the main research problem on
what international youth find relevant in education for sustainable development.
Before presenting the actual studies, this thesis will present a theoretical framework
that is needed to understand the studies, and the discussion to follow. This framework is
presented in Chapters two and three, discussing sustainable development and relevant
3
education, respectively. The theoretical framework will help the reader understand the
importance of this thesis, as well as why a students’ perspective was chosen.
The fourth Chapter presents the methodological framework for the study, presenting
how descriptive research, cases studies and elements of grounded theory were used in this
thesis. The reason for selecting these particular methodologies is also justified. Chapter
five summarizes the six studies presented in this thesis and is divided into four sections,
based on the research questions. The methods used for data collection and the main results
of each study are presented in this chapter. The sixth Chapter examines the validity and
reliability of the thesis. The seventh and final Chapter of this thesis brings the six studies
together by discussing the implications of the findings and the thesis as a whole. The
Chapter also suggests areas in which further research should be conducted.
4
5
2. SUSTAINABLE DEVELOPMENT AND ITS EDUCATION
In order to create a better world, society must learn to take the limits of the
environment into consideration (see e.g. Meadows, Meadows, Randers, & Behrens, 1972).
However, overconsumption of resources is currently the norm, causing many
environmental challenges, such as climate change, eutrophication and erosion of
farmlands. In order to prevent these challenges from escalating, education on how to reach
a sustainable level of consumption is needed.
This chapter first discusses what sustainable development means and why achieving
sustainable development is important. It then outlines the history and the current
discussion on education for sustainable development. Finally, this chapter presents a
specific case related to education for sustainable development, namely climate change
education.
2.1. Sustainable Development
Sustainable development has numerous definitions (Johnston, Everard, Santillo, &
Robert, 2007), though the most common and well known one is the definition from the
Brundlands’ report (World Commission on Environment and Development (WCED),
1987). In the report, sustainable development was defined as development that meets the
needs of the present without compromising the ability of future generations to meet their
own needs (WCED, 1987).
Typically sustainable development is thought to consist of three pillars, namely, the
environment, the society and the economy. Other pillars, such as culture, are also
commonly presented (Jon Hawkes, 2001), though not accepted as widely as the prior
three. As sustainable development attempts to combine environmental concerns with
socio-economic issues (Hopwood, Mellor, & O'Brien, 2005), sometimes contradicting
interests are at play (see e.g Ehrlich & Holdren, 1971; Robinson, 2004). On the one hand,
overconsumption of natural resources is causing society to be more concerned for the
wellbeing of the environment and future generations. But on the other hand, psychology
has shown that humans are loss adverse (Kahneman & Tversky, 1979) and often chose
immediate gratification over delayed gratification (Mischel, 1973). In the context of
sustainable development, this means that individuals value the already achieved high
living standard so much that taking environmental actions with a decrease in living
standards is not compelling.
Furthermore, it is not uncommon for people to believe that the development of science
and technology will solve the environmental problems society is facing. However, as has
been pointed out by Ehrlich and Holdren, (1971) there are a number of factors that are
causing an environmental impact. At least three factors affect the impact (I) on the
environment, namely population (P), affluence (or goods consumed per capita) (A) and
technology (T). The role of these three was debated already in the 70’s (Commoner, 1972;
Ehrlich & Holdren, 1971) resulting in the formulation of the following equation:
6
(1) I = P x A x T
Since the creation of the model, other, more complex, models have also emerged (see
e.g. Hynes, 1993). However, the bottom line in the different models is that science and
technology on their own do not seem to be sufficient to decrease environmental impact.
For instance, the technology currently available can help decrease environmental impact,
but it is not enough to diminish the negative impact caused by an increasing population
and affluence (York, Rosa, & Dietz, 2002).
Currently, at least in the western world, our culture is driven by affluence. As affluence
is strongly linked with economics, it can cause an imbalance in the three pillars of
sustainable development. Some feel that this imbalance is causing harm to society, as is
depicted in Figure 2.
Figure 2. The imbalance of the three pillars of sustainable development (A31, 2006)
Therefore, for people to understand the role of science and technology in solving
environmental problems, education for sustainable development (ESD) is needed. For
such education to be useful, it should take into consideration all three pillars of sustainable
development, meaning that it cannot be subject specific. Education needs to be
multidisciplinary, as will be highlighted in the following sections.
2.2. Education for Sustainable Development
For the past few decades, sustainable development has been seen as an important part
of education. The UN especially has been strongly pressing the agenda for ESD from as
7
early as 1992 (see United Nations Conference on Environment and Development, 1992),
when the importance of ESD was highlighted in Agenda 21. The UN also declared 2005-
2014 the decade of education for sustainable development (UNESCO, 2015) and is
continuing to pursue ESD through the Global Action Project (GAP) (UNESCO, 2014),
which, more or less, continues from where the decade of education for sustainable
development left off.
Partially due to the heavy actions by the UN, the importance of ESD has been noted
widely, resulting in the creation of a number of models on how to incorporate ESD (e.g.
de Haan, 2006; McKeown, Hopkins, Rizi, & Chrystalbridge, 2002; Paden, 2000) Many of
these models have some traits in common. The most essential elements were summarized
by Eilks & Hofstein (2014) as follows:
x Learning about natural and man-made environments using an integrated view of
their social, political, ecological and economic (and possibly cultural) dimensions,
including involvement at the local and global levels
x Focusing on participatory learning while aiming to promote citizenship skills
through an ethics- and values-driven approach
x Orienting learning on system-based thinking, including the use of
interdisciplinary, learner-centered, experiential and inquiry-based methods
x Focusing on life-long learning as a perspective which integrates formal and
informal education
In sum, the list suggests that societal issues need to be implemented thoroughly,
interdisciplinary approaches need to be adopted and pedagogical methods need to be
changed (Eilks & Hofstein, 2014). Needless to say, implementing these aspects into
science education brings about some challenges.
One of the greatest challenges may be to incorporate societal issues into science
education. Educational researchers have already argued for such an approach for decades
(e.g. Bybee, 1987; Hurd, 1970). Yet, even today, science education is sometimes largely
disattached from its societal context (Gilbert, 2006). Of course, there is hope that the
realization of the importance of sustainable development may change this, but if history is
any indication, it will take time.
On a larger scale, moving towards interdisciplinary education would require a
paradigm shift from a traditional, subject specific approach, towards a citizenship
education approach. This change has already started to take place, since during the past
few decades there has been ongoing discussion on incorporating education in science,
technology, society and environment (STS and STSE) (e.g.Bybee, 1987; Pedretti & Nazir,
2011). Furthermore, bringing socio-scientific issues (SSI) into science education have
been highly encouraged (e.g. Ratcliffe & Grace, 2003). These would not only help
students understand the relationship between science and society, but also bring to
discussion many moral issues crucial for citizenship education. In essence, the paradigm
shift should include aspects of economics, social sciences and the humanities into science
education (see Eilks & Hofstein, 2014)
8
Someone may wonder why all of these fields should be brought under one roof rather
than teach them as separate subjects, as has been done previously. The main reason for
this is that students often have difficulties transferring knowledge to new situations (e.g.
Gilbert, Bulte, & Pilot, 2011). Therefore, if the multidisciplinary dimensions of
sustainable development are taught in different classes without teachers helping students
make the links between the subjects, the links may not be made at all.
The ESD models also call for new pedagogical approaches, such as student-centered
education and inquiry-based learning. A more extensive summary of the different
educational approaches was presented by Juntunen and Aksela (2014) in the following
figure:
Figure 3. Methods to approach ESD education (Juntunen & Aksela, 2014).
As shown in Figure 3, using multiple pedagogical approaches in ESD is needed. This
shift from traditional pedagogical methods will require effort from teachers. However,
moving towards such new methods is reasonable, as the aim of ESD is not only for
students to gain knowledge, but also to learn to make decisions and to take action (e.g.
Jensen & Schnack, 1997). Furthermore, students should learn to be responsible, not only
for themselves, but for future generation as well (de Haan, 2006).
2.2.1 Climate change education
Currently, one of the major environmental threats hindering sustainable development
is climate change (Rockström et al., 2009). Although climate change is a natural
phenomenon, in the past two centuries it has been enhanced by human behavior (IPCC,
2014). This has not only caused faster than usual changes in the environment, but has also
raised societal questions on the sustainability of human consumption, and on how society
is prepared for the possible consequences of climate change (see Meadows et al., 1972).
Because of the large amount of environmental and societal issues involved in climate
change, it is relevant for future citizens to understand the topic. Education on climate
change has already been implemented into many national curricula (Schreiner, Henriksen,
9
Kirkeby, & Pål, 2005), but in many cases the focus is on the scientific aspects, the societal
aspects getting little or no consideration (e.g. Gayford, 2002; Schreiner et al., 2005).
However, educational experts have argued that for students to become scientifically
literate, students should understand the link between societal and scientific issues (e.g.
Zeidler & Keefer, 2003).
Climate change education needs to include scientific facts on how the climate works as
a system. Researchers (Shepardson, Niyogi, Roychoudhury, & Hirsch, 2012) have
suggested that a system analysis of climate change should include at least the following
six dimensions:
1. Natural causes and changes to the climate system
2. Atmosphere and pollution
3. Snow and ice levels
4. Oceans (levels, temperature and life)
5. Land and vegetation
6. Human impact
(See Shepardson et al., 2012 for more details)
These dimensions are important in understanding climate change as a system, but as is
discussed further in Study II, they don’t encompass societal and moral discourse
extensively. In order for students to understand the other dimensions of climate change,
some researchers (see e.g. Moser & Dilling, 2004; Schreiner et al., 2005) have argued that
climate change education should include political, economic, ethical and psychological
aspects in addition to the scientific ones. However, as the array of aspects that should be
taught is wide, teachers may be incompetent to teach climate change (e.g. Ocal, Kisoglu,
Alas, & Gurbuz, 2011; Papadimitriou, 2004) and would rather maintain the integrity of
their subject, rather than teach on multidisciplinary aspects (Gayford, 2002). Furthermore,
as climate change involves many moral questions, the teachers own emotions can affect
their teaching (Lombardi & Sinatra, 2013). One way to overcome these challenges is to
move more towards student-centered education and non-formal education, as they provide
the opportunity to diverge from the traditional way of teaching, where the teacher needs to
be the “all knowing expert”.
10
11
3. RELEVANT EDUCATION
The primary goal of education, whether it is regarding green chemistry, sustainable
development or climate change, is for it to be relevant. Unfortunately, learners find
science education ‘irrelevant’ for themselves as well as for society (Dillon, 2009; Gilbert,
2006). This has contributed to science education being unpopular among students (e.g.
Osborne, Simon, & Collins, 2003). Moving towards more relevant science education is
clearly needed, but the challenge is that there has been ambiguity on what is meant by
relevant education (see Stuckey et al. 2013 for more details) and to whom it should be
relevant.
This chapter first presents a way to define relevant education and then discusses some
pedagogical methods that can be used to achieve relevant education.
3.1. Defining Relevant Education
In the late 50s and early 60s, science education was primarily used as a tool to recruit
future scientists, medical doctors and engineers (DeBoer, 2000). This continues to be so in
many western countries (Osborne & Dillon, 2008). Such an approach makes science
education only relevant for those students who want to pursue a science career, and
therefore, was strongly criticized in the late 60s and 70s (see e.g. Osborne et al., 2003). As
a result, education reforms were made with the aim that students would be “scientifically
literate”, or that science education would be “science for all” (Dillon, 2009). The goal was
to enforce social and personal goals for science education. However, it was not until the
80s that societal issues started to play a larger role in science education (Yager &
Hofstein, 1986), and not until the 90s that socio-scientific issues were starting to be used
as the basis to teach current and future implications of science and technology to society
(Marks & Eilks, 2009). However, during the past few decades education has become
more relevant for students. Even today the science contexts taught are sometimes largely
detached from their societal, ecological and economic contexts (Gilbert, 2006).
In order to address this problem, Stuckey et al. (2013) have suggested that in order for
education to be relevant, it needs to be relevant to the individual, to society and to the
future vocation of the student. In their work, they define individual relevance as something
that meets the direct needs of the students by providing them with skills and knowledge to
understand the world around them, pass school exams and feed their curiosity. Societal
relevance is defined as giving students the tools to become active members of society, and
putting their education into a context that helps them better understand the world around
them. Vocational relevance refers to giving students the skills and knowledge they need to
find work, and become useful members of the workforce. Each of these three dimensions
has a present and future dimension, as well as an intrinsic and extrinsic dimension (See
Stuckey et al. 2013 for more details). In order to make education relevant for the learner,
all of these dimensions of relevance should be addressed. However, the societal
dimension is often neglected in science education (Hofstein et al., 2011).
12
In order to address all three domains of relevance in an integrated way, Eilks and
Hofstein (2014) see that the best approach is to build the science curricula around
controversial issues where science and society interact, also known as socio-scientific
issues (see e.g. Sadler, 2011). One approach in dealing with such socio-scientific issues is
to use sustainable development as a context, as it interlinks scientific and societal aspects,
connecting them to the environment and to economics.
In order to attain relevant education, a variety of approaches should be used. The next
sections will present student-centered education, education for action competence, non-
formal education and education for the gifted, as examples.
3.2. Student-Centered Education
The aim of student-centered education is to provide a learning environment in which
the students take an active role in their learning (Hannafin, 1992) by deciding all or some
of the learning goals, resources and activities used (Jonassen, 2000). Such learning can be
supported by interactive activities that meet the students’ unique learning interests and
style (Hannafin & Land, 1997). However, in order to be successful, student-centered
learning must have an interesting problem or question to tackle, so that the students stay
motivated (Pedersen & Liu, 2003). Also, the teacher needs to be able to acknowledge and
enforce students’ interests, talents, learning styles and different stages of development
(Pedersen & Liu, 2003; Teaching Excellence in Adult Literacy (TEAL), 2011).
Though student-centered education seems to improve at least students’ critical thinking
skills, creativity, motivation and student satisfaction (Cornelius-White, 2007), it has not
been strongly implemented in schools (Estes, 2004). The reasons for this may lie in
curriculum restrictions as well as the reluctance of teachers to change their teaching habits
(Richardson, 1998).
However, student-centered learning has great potential in overcoming some of the
educational challenges that hinder moving towards ESD and relevant education. For one, a
student-centered approach allows personalized learning, making it possible to emphasize
the three dimensions of relevance in different ways to different students. Furthermore, it
can compensate for a teachers lack of competence in a multidisciplinary field, such as
climate change. In fact, researchers have argued that teachers’ lack of competence is the
main reasons why student-centered education is important (Pekel & Özay, 2005). In
addition, as student-centered learning encourages setting personalized learning goals, it
can help students become life-long learners.
In this thesis, Study I and II examine the type of questions students ask about ESD
and discuss how students’ questions could be used to move further towards a student-
centered learning approach.
13
3.1.1 Action competence
In the context of environmental education and sustainable development, one of the
primary goals for student-centered education is that students learn to take action on
environmental concerns (see Jensen & Schnack, 1997). In the ESD model presented in
section 2.1, such an ability is encompassed in the idea of teaching students to become
active citizens, but it is also commonly referred to as action competence (e.g. Jensen &
Schnack, 1997).
Jensen and Schnack (1997) define action competence as the ability and the will to take
action on certain issues. They make a clear distinction that action competence is not
merely behavioral change, but rather, they imply that it is an attitudinal change, resulting
from understanding why actions are needed. They also make a distinction between action
competence and activity. They argue that educators may, at times, try to move away from
the academic approach of environmental education by introducing activities, such as
visiting an “untouched” forest, or doing hands-on experiments on the chemical, physical
and biological properties of the water in a nearby pond. However, as such, these activities
do not increase a students willingness to take action, and therefore, do not meet the
criteria for action competence.
Providing science education with the aim of increasing students’ action competence
would require the incorporation of student-centered education and a multidisciplinary
approach. However, a shift towards such education would not only be significant for the
environment, but could help students notice the individual and societal relevance of
science.
Though action competence (Jensen & Schnack, 1997) and active citizenship (Eilks &
Hofstein, 2014) are seen as crucial parts of ESD, studies on students’ action competence
or their perspective on active citizenship are scarce. In this thesis, Study III examines the
kinds of actions that students take as active citizens. The thesis will also discuss how
knowledge on these actions could be used to make science education more relevant.
3.3. Non-Formal Education
Since the 1960s there has been an increasing amount of discussion on the need for
out-of-school education (Belle, 1982). Originally, out-of-school education was aimed for
those who did not have the opportunity to attend formal education, but today it is used to
respond to a large array of new and different demands of education, such as educating
particular groups of students (e.g. scientifically gifted) in a specific field (e.g. sustainable
development) (Finland's Science Education Centre, 2012).
Out-of-school education, such as camps and fieldtrips (Eshach, 2007), are commonly
referred to as non-formal education, as it takes place in less formal settings than formal
education. However, non-formal education also has other distinctions from formal
education. The most easily notable difference is that non-formal education is usually
voluntary for the students, learning is not evaluated, and learning is not restricted to
national guidelines, such as a curriculum (Eshach, 2007). This freedom gives non-formal
14
education the possibility of dealing with issues either more specifically, or more
holistically, depending on what the educators want. It also gives the freedom to deal with
relevant, cutting-edge topics that are not yet present in national curricula.
Non-formal education has many benefits, such as giving students the possibility to
learn more about the issues in which they are interested. Furthermore, non-formal
education has been shown to positively affect the attitudes and motivation of students. For
instance, Pedretti (2002) has stated that science fieldtrips and trips to science centers can
increase students’ interest and sense of wonder towards science. This then increases their
motivation, enthusiasm and eagerness to learn (Pedretti, 2002). What is also significant is
that these attitudes can persist over time (Rennie, 1994; Rhodes, 2013) and can result in
further engagement in the topic (Germann, 1988). In addition, the social interactions in
non-formal education can be significant, as students can reflect what they have learned
with teachers and like-minded students (Rahm, 2004).
In the summary of ESD models (see section 2.1) it was stated that lifelong learning
should be supported by the integration of informal and formal education. However, non-
formal education should also be added to the list, as it has much potential, as will be seen
in the results from studies IV, V and VI.
3.4. Gifted Education
The studies in this thesis occasionally refer to gifted education, or education for the
gifted.
Defining gifted education is relatively easy as, in essence, it refers to educating a
specific group of students that are found to be gifted in a particular field, such as science.
Defining giftedness, however, is more challenging. Over the years, giftedness has been
given many definitions (see e.g. Subotnik, Olszewski-Kubilius, & Worrell, 2011) and the
complexity of finding a definition is seen in a book written in 1986 by multiple authors
(Sternberg & Davidson, 1986). The book contained more than a dozen definitions for
giftedness. Furthermore, two decades later, when a new edition of the book was published
(Sternberg & Davidson, 2005) the number of concepts defining giftedness had only
increased. Researchers have tried to categorize the perspectives there are on giftedness,
coming up with at least five things that contribute to giftedness. These are intellectual
ability (high IQ), emotional fragility, creative-productive giftedness, talent development in
various domains, unequal opportunities and hard-work and practice (Subotnik et al.,
2011).
As there are many viewpoints on what giftedness is, reaching a concensus is
challenging. However, most researchers do agree that the definitions have some
similarities, especially in the non-cognitive aspects (e.g. motivation, self-concept,
expectations). Many of the concepts also note the importance of social aspects (e.g.
environment, family background) and agree that giftedness typically correlates with
performance (Sternberg & Davidson, 2005).
A gifted student can, therefore, be defined as someone who achieves well in a
particular field, even compared to other high functioning individuals (Subotnik et al.,
15
2011). This, of course, is a simplification of the vast array of definitions on giftedness, and
does not, for instance, consider motivation, which plays a role in future achievement
(Subotnik et al., 2011). Furthermore, it does not distinguish between cognitive, non-
cognitive and social aspects, which can all affect achievement. However, as any definition
will have its limits, in this thesis gifted students refer to those students who are motivated
to study science and have shown their motivation through achievements in and out of
school.
Previous studies have shown that an ideal learning environment for gifted students
supports holistic learning (Tirri, 2011; Tirri, 2012). This means acknowledging the
students’ academic, social and emotional needs, in essence, their personal growth (Tirri &
Kuusisto, 2013). Research has shown that especially social support is important for gifted
youth, as their educational outcomes can depend on whether their social environment
value or devalue their academic efforts and achievements (Bliuc, Ellis, Goodyear, &
Hendres, 2011). Receiving this social support from both like-minded youth and teachers is
important (Tannenbaum, 1983). In addition to social support, gifted students require an
advanced curriculum (Colangelo, Assouline, & Gross, 2004) that reflects their interests
(Subotnik et al., 2011) and gives them the possibility to advance in their learning at a
faster pace (Colangelo et al., 2004).
One way to support gifted students is through non-formal education (Tirri & Kuusisto,
2013). For instance, previous studies have shown that extra-curricular programs, such as
camps, have a positive effect on gifted youth. Such programs can increase the quality of
peer relations (Rinn, 2006), increase self-confidence, thinking skills, motivation and
autonomous learning (Moon, Feldhusen, & Dillon, 1994). Furthermore, there are
indications that these affects persist over time (Moon et al., 1994), though some
researchers are more skeptical about the long-term effects, arguing that gifted students will
achieve well, despite non-formal educational programs (see Hany & Grosch, 2007).
Though the positive effects of non-formal education on gifted students is noted, there
is a limited amount of studies looking at what type of non-formal education is relevant to
the gifted youth. This thesis sheds light on this issue through Studies IV, V and VI.
16
17
4. METHODOLOGICAL FRAMEWORK
This thesis combines characteristics of a descriptive research (see Cohen, Manion, &
Morrison, 2008) and a case study approach (Cohen et al., 2008) with hints of a grounded
theory approach (Denscombe, 2010). Characteristics of a descriptive research are clearly
present, as this thesis uses surveys to describe students’ points of view and attitudes
towards sustainable development and its education. Simultaneously, characteristics of a
case study are present, as it examines a particular non-formal learning environment, the
Millennium Youth Camp, and uses this as a case to contribute to the discussion on the
research problem. Grounded theory, on the other hand, is not used in its pure form, but
rather, certain characteristics that were found useful for this thesis were “borrowed”.
This chapter defines these three approaches, explains how they were used and why
they were chosen. Furthermore, the last section of this chapter addresses the benefits and
challenges of mixing different approaches.
4.1. Descriptive Research
Typically the main concern of descriptive research is to study beliefs, points of views,
attitudes and effects being felt by the person/group under study (Best, 1970). The data is
typically gathered at a certain point in time with the intention of describing conditions,
identifying trends and patterns, or to determine the relationship that prevails between
events (Cohen et al., 2008). Depending on the aim of the research, it can be approached
using a variety of different research strategies, such as survey research, longitudinal
studies, cross-sectional studies or trend studies (Cohen et al., 2008). In this thesis, the most
commonly used methodology is survey research, but a longitudinal study is also
implemented.
Survey research was selected as one of the research methodologies for this thesis, as it
gives the possibility to collect a large amount of data at a specific point in time
(Denscombe, 2010). Moreover, survey research works well when there is a clear and
narrow target of what type of information needs to be obtained (Denscombe, 2010). In this
thesis, this was the case with RQ1 and RQ3, which examine the type of questions and
expectations students have about education for sustainable development before attending a
non-formal educational program that deals with sustainability issues. Survey research was
also partially used to examine how students’ expectations can be met (RQ4).
The survey research conducted in this thesis used a non-probability sample that was
“hand-picked” (see Denscombe, 2010) to collect the data. Regarding RQ3 and RQ 4, the
decision to do so is clear, as a sample of students applying for a non-formal educational
program was needed. However, with RQ1, the decision to do so may not seem so straight
forward. Someone might argue that the sample does not represent a typical science class-
room, as all the students in the sample are interested in science. In this, they would be
correct, and the argument would be significant if the aim was to answer RQ1
quantitatively. However, in this thesis, RQ1 is mainly answered qualitatively, although
18
Study I does have a quantitative aspect to highlight that even students interested in
science present a significant amount of non-scientific questions. The qualitative approach
was chosen to contribute to the wider discussion on what type of teaching methods can be
used to make education for sustainable development more relevant. From this perspective,
a non-probability sample has its benefits. Namely, students interested in science can be
assumed to present a wider range of different types of questions than students not
interested in science. Therefore, a smaller sample was needed to get a good representation
of the types of questions students ask.
Though descriptive research is beneficial for many purposes, it is not very useful in
sensitive and complicated matters. As RQ4 had such elements, a case study approach was
seen as an appropriate approach to dealing with these issues.
4.2. Case Study
A case study is a research approach that focuses on a single instance, or a phenomenon
by trying to provide an in-depth view of the experiences, relationships and processes that
occur in that instance (Denscombe, 2010). They are set up in a controlled environment,
such as a school or a camp (Hitchcock & Hughes, 1995), and they aim to find principles
from the case, which can then be generalized to other similar situations or cases (Robson,
2002). In other words, case studies often try to catch a close-up of reality by trying to
portray “what it is like” to take part in a particular experience, and what kind of thoughts
and feelings that might evoke in the person taking part (Cohen et al., 2008).
Case studies have several strengths compared to other research methods. These include
catching unique features that may otherwise be lost in larger scale data. They are strong on
reality, they help understand other similar situations and they can embrace unanticipated
events (Niset & Watt, 1984). However, they also have their limitations. For instance, they
are not easily cross-checked, causing possible personal and subjective bias, and the results
may not be generalized except where other researchers and readers see their application
(Niset & Watt, 1984).
In this thesis, a case study approach was used to answer RQ4, as an in-depth, holistic
view of relationships and processes was the aim. The data was collected using
observations (of documents) (Study V) and questionnaires (Study IV & VI). Out of the
studies contributing to answer RQ4, Study IV is a case study in its’ own right and
together, Studies IV, V and VI contribute to describing the case from a wider perspective.
4.3. Grounded Theory
Grounded theory is a research approach that aims to create a theory based on data
collected from the field, contrary to the more common method of first creating a theory on
the abstract level and then testing it in practice (Denscombe, 2010). Though grounded
theory has been used in many ways since its first creation in the late 50’s and early 60’, by
19
Glaser and Strauss, some general principles do exist. First, in a grounded theory approach,
data collected from the field is analyzed without trying to fit it into an existing theoretical
framework. Rather, the researcher should keep an open mind when analyzing the data to
see if something new and unexpected emerges. Only after the data is analyzed and
interpreted, are the findings compared to existing research. If a new theory emerges from
the data, more data is collected to test the results (Denscombe, 2010). Therefore, grounded
theory is not a theory as such, but rather, an approach to generate a theory from data
(Bryman, 2008).
Due to its characteristics, grounded theory is typically quite adaptable and pragmatic
and is especially useful in systematically analyzing qualitative data, as well as formulating
theories from the data collected (Denscombe, 2010). However, one of the major
challenges is that precise planning of grounded theory research is difficult (Denscombe,
2010). Furthermore, it requires the researcher to be open-minded to new ideas, as there
should not be any theoretical framework guiding the analysis of the data. This has also
caused some to criticize the approach as “empiricist”, as it does not acknowledge the
complex nature between theory and data collection, but rather, assumes that the
explanation is in the data and is only waiting to be “discovered” (Denscombe, 2010).
In this thesis, Studies II (RQ1) and III (RQ2) use elements of grounded theory,
though neither of the studies use the methodology in its purist form. In Study II, data was
collected using a questionnaire and analyzed with inductive and deductive qualitative
research. Some of the categories formed in the analysis were based on previous research
(deductive), but most of the categories were new. Only after discovering the categories,
other research supporting the categorization was found. However, as the formed categories
were not tested again through field work, the final stage of a grounded theory approach
was not completed. In Study III, the data was collected through unstructured interviews,
and again, the data was analyzed using inductive and deductive content analysis. Only
when analyzing the interviews, did the researchers start to realize the trends depicted in
the study. These trends were then used to create a theory, which was compared with other
similar research. The researchers then analyzed more data (though new data was not
collected) to strengthen their findings. Again, the stage of collecting new data was omitted
in this study, and therefore it does not meet all the criteria for a grounded theory approach.
Regardless, both Study II and III of these studies benefitted from using parts of the
grounded theory framework.
4.4. Mixed methods research and triangulation
As is done in this thesis, it is not uncommon to use several different research
approaches within a single research project. Mixing different approaches can help
overcome many of the problems of using only a single approach, such as bringing
completeness to an issue of interest, answering several research questions simultaneously
and helping explain the results obtained in a more in-depth way (Bryman, 2008).
20
Mixing methods can be accomplished done in several ways, such as mixing several
qualitative or quantitative research methods (Denscombe, 2010). However, only when
both qualitative and quantitative methods are mixed together, is a research said to have a
mixed methods research approach (Bryman, 2008). This thesis does this by
implementing some quantitative data (Study I and Study V) to support the qualitative
data. However, as most of the studies in this thesis are of qualitative nature, the scale
between quantitative and qualitative data is skewed, and therefore other ways to increase
the reliability of the results are also used.
When a study examines things from more than one perspective, but does not
necessarily do so by analyzing both qualitative and quantitative data, the process is called
triangulation (Denscombe, 2010). This thesis uses three ways of triangulation, namely,
methodological triangulation, time triangulation and investigator triangulation
(Denscombe, 2010). These are used in order to the improve accuracy of the results as well
as provide a more complete picture on the topic. More information on how triangulation is
used, is explained in the next Chapter and the studies themselves.
21
5. DESCRIPTION OF THE STUDIES
This chapter describes the six studies that construct this thesis. The chapter is divided
into four parts according to the four research questions.
The first part presents two studies (Studies I & II) that examine the type of questions
students ask about ESD. The second part presents Study III, which looks at the kind of
actions students take in order to make the world a better place. The third part presents
Study IV(a), which examines the type of expectations students have when applying to a
non-formal educational program with a focus on sustainable development. The final
section presents three studies (Studies IV(b), V and VI) which examine how non-formal
can help meet the educational expectations of students.
The data collected for all of the six studies has a relation to the Millennium Youth
Camp (MYC). The MYC is an international camp that has been held in Finland once a
summer in 2010-2014. The attendees of the camp are 16-19 -year old students from all
around the world. The campers are selected through a rigorous three stage selection
process, with the following stages: In stage 1, students describe their previous science
related accomplishments, present questions to which they would want answers during the
camp and write about their motivation towards science and applying to the camp. The top
100-200 applicants are then selected for stage 2 of the application in which students have
to complete an individual project work on a specific theme assigned to them by specialists.
These projects are related to the students’ areas of interest, presented in stage 1. In stage 3
the candidates with the best projects are interviewed and the final selection is made. The
selected campers (30-60 students) then start to work on a group project online, two months
before the camp. This process is guided by a specialist from a university or a private
company. During the camp, attendees continue working on their project, as well as attend
many other kinds of activities (see Study V and VI for more details).
The data used in this thesis was collected through self-completion questionnaires,
essays and interviews and was analyzed using both quantitative and qualitative content
analysis, as is presented in the following sections.
5.1. Students’ Questions on Sustainable Development
For student-centered learning to be successful, it must have an interesting problem or
question to tackle (Pedersen & Liu, 2003). However, research on students’ interests on
themes related to sustainable development is scarce, if non-existent. Therefore, in order
for ESD to move to more student-centered approaches, studies on student interest are
called for. That said, it is not so important to know whether or not the students are
interested in ESD in general, but rather, to know what aspects of the issue they find
relevant. In order to start this examination, two studies were conducted on students’
questions on sustainable development and presented in this section. Study I looks at
questions students ask about sustainable development from a broad perspective, whereas
Study II looks at questions asked about climate change in specific.
22
This section first presents how the data for these two studies was collected and
analyzed. It then discusses the results and goes on to summarize the key findings. The
contribution of these two studies to the research problem of this thesis is discussed in
Chapter 7.
5.1.1 Data collection and analysis
Study I used deductive content analysis to examine the type of questions students ask
about sustainable development. The data was collected from the first stage applications to
the 2011 MYC. In the application, students were asked to select one of the following five
theme groups to which they wished to apply: Climate change, Renewable energy and
resources, Water, ICT and Applied mathematics. As this study focused on the type of
questions students ask in a context of natural science, and more specifically, on
sustainable development, the applications for the ICT and Applied mathematics were
omitted from this study.
The students applying to the Climate change, Renewable energy and resources, and
Water groups were asked to present questions to which they would want answers during
the camp. The questions presented by applicants from Europe and Asia (N=544) were
analyzed through deductive content analysis. The questions were categorized into
scientific, societal and moral questions. Some questions presented by the students held
two or more of these dimensions within them and so, a ranking system was formulated,
making it possible to categorize each question into only one of the three dimensions (see
Study I for more details).
To assure the reliability of the analysis, a sample of 100 questions was analyzed into
the three categories by a researcher not involved in writing the paper. These results were
then compared to the analysis of the authors. The inter-rater reliability (ir) between the
two researchers was calculated with the formula:
(2)
The level of agreement was found to be reasonable (ir=0.83). The categorized
questions were then analyzed using non-parametric statistical methods and cross-tabulated
with gender (male/female), continent of origin (Asia/Europe) and camp themes (climate
change/renewable energy/water). Analysis was done using IBM SPSS Statistics 21.
The reason for using a quantitative approach in Study I was to first get a broad
understanding of the type of questions students ask in a science context. As students were
expected to ask a wide range of questions, it was rationalized that a quantitative approach
would provide an initial understanding on how relevant students find the types of
questions presented. Though Study I gave room for inductive content analysis, it was
guided by deductive content analysis, as the groups formed stemmed from previous theory
of the type of aspects students find relevant. The deductive content analysis also affected
the descriptions of the three groups formed in Study I, namely, academic, societal and
moral interests.
23
To answer RQ1 in more depth, more information was needed on the different types of
questions observed in Study I. Study II was carried out for this purpose. Study II
analyzed the questions of students applying to the MYC Climate change group (in 2011).
Applicants from Asia and Europe (n=200) presented 355 climate change related questions,
which were examined with deductive and inductive content analysis. In the analysis, the
questions were categorized into five groups and the reliability of the descriptions of the
groups was tested by a researcher not participating in writing the paper. This was done by
giving the external researcher the descriptions of the five groups and asking them to
categorize a randomly selected sample (10%) based on the descriptions. Their analysis
was then compared to the analysis of the first author by using Cohen’s kappa analysis:
(3)
where Pr(a) is the observed agreement between the researchers and Pr(e) is the expected
level of agreement if agreement happened by chance (Cohen, 1960). The Cohen’s kappa
coefficient N was calculated using IBM SPSS statistics 21. The agreement between the two
researchers was found to be good (К=0.82). Furthermore, correlation between the obtained
groups was analysed and the difference between gender, continent of origin and age were
analysed with the Mann-Whithey U-test.
5.1.2 Results
Study I found that students mainly ask scientific questions (57%) in issues related to
sustainable development, but that societal (23%) and moral (20%) questions were also
common. The nature of the questions differed depending on which theme group the
students applied to, but consistencies between the theme groups were also found. For
instance, in both the climate change and water group, students were concerned about
global effects.
From the scientific issues, students were most typically interested in the relation
between scientific discovery and technological developments, as well as how scientists do
research, and how the quality of the research and findings are tested. Scientific questions
were more common among male than female students. The students’ societal questions
showed that students want more information on how countries co-operate and make global
decisions in issues such as the use of renewable energy and climate change mitigation.
The societal questions also echo a concern for the overuse of natural resources. Female
students were more inclined to ask societal questions than male students. The typical
moral questions showed a concern for the planet and a willingness to take action to solve
environmental problems. More commonly, the moral questions were related to what
individuals can do, but some students also asked broader questions, with a societal
dimension such as, what societies could do to make the world a better place.
Study II brought more depth to students’ questions by examining the type of questions
asked about climate change. The analysis of students’ questions showed that students are
interested in a wide range of climate change related issues, which can be categorized into
24
five main groups: Climate System Framework (33%), Effects on Humans (11%), Solutions
for Climate Change (37%), Raising Awareness (6%) and Human Action (13%). The
questions categorized into the Climate System Framework group showed that students
want further understanding in the science of climate change, and furthermore, they want to
understand how science is done (the Nature of Science, NOS). The questions also showed
that students want to understand how to examine the trustworthiness of scientific findings.
Students also wanted to know how the changing climate will affect humans, both
societally and economically. They also showed great interest in knowing more about what
can be done to combat climate change. Most of these questions were directed at
individuals, but some questions were more societal, pondering how to increase the use of
renewable energy, for instance. Related to these questions, were those where students
asked what governments and societies are already doing to combat climate change
(Human Action). In addition, some students also found it important to learn how to raise
the awareness of others.
5.1.3 Summary
The aim of Study I and Study II was to find out what type of question students ask
about sustainable development in general and climate change in specific. Study I
examined the issue mainly from a quantitative perspective, whereas Study II provided
qualitative insight. The findings of these two studies have many similarities, as both
reflect the fact that students ask a wide range of scientific questions related to sustainable
development and climate change. Both studies also show that students ask a wide range of
societal questions, and often have moral issues embedded into their questions. The
quantitative analysis of Study I shows that academic (57%) questions are most popular,
but that students also ask societal (23%) and moral questions (20%). The qualitative
analysis of Study II shows that students’ questions on climate change can be analysed
into five distinct groups, namely: Climate System Framework (33%), Effects on Humans
(11%), Solutions for Climate Change (37%), Raising Awareness (6%) and Human Action
(13%). The findings of the two studies give insight into what type of problems students
will find interesting to grapple with in science class.
5.2. Students’ Actions to Make the World a Better Place
As was presented in the introduction, implementing citizenship education into science
education has already started to take place. However, defining “good citizenship” is
difficult, or maybe even impossible (see Study III for more discussion). Regardless, it is
beneficial to consider how students’ view citizenship and what type of actions they take as
citizens, regarding sustainable development. To gain understanding on this, Study III,
presented below, examines what type of actions students are already taking as
participatory citizens and how knowledge on these actions can be used to improve science
education.
25
5.2.1 Data collection and analysis
In Study III, 35 students selected to the 2013 Millennium Youth Camp were
interviewed, with the aim of finding out what type of actions students are taking to make
the world a better place. The interviewed participants came from all corners of the world,
representing 21 different countries.
The interview questions were developed by the researchers through two pretests, one
conducted on pre-service teachers and the other conducted on 16-18 year old students
from a prestigious high-school in Helsinki, Finland. Through discussion and testing, the
researchers developed the interview questions to best answer the research question.
Themes of the interview included:
x Can humanity solve the problems it is currently facing?
x Who is responsible for solving these problems?
x How do the students themselves contribute to solving these problems?
(see Study III for more details)
After the interviews were transcribed, the data was analyzed in two phases. In the first
phase, the data was analyzed using inductive content analysis to reduce the content into
categories. In the second phase, these categories were organized to form conceptual
categories using both inductive and deductive content analysis. As a result, the data was
categorized into three conceptual categories, described in the Results section.
To ensure reliability in the grouping, two researchers independently analyzed the
transcripts of the interviews using the descriptions of the three conceptual categories that
were created based on the first round of analysis. Inter-rater reliability was tested with
Cohen Kappa (see section 5.1.1), showing that the reliability of the categorization was
good (К=0.80-0.88).
5.2.2 Results
Study III shows that students take various actions in order to make the world a better
place. These actions can be divided into three types, namely: personal responsible actions,
participatory actions and preparation for the future.
Personal responsible actions refer to actions that students take on a personal level, such
as helping friends, recycling and giving money to charity. The majority of students
interviewed were doing some sort of personal responsible actions. The reasons to take
personal responsible actions were typically due to virtues, such as kindness and honesty or
due to societal responsibility. Some students also said they did these actions in the hopes
of influencing others to do the same.
The majority of the students involved in the study were also making the world a better
place though participatory actions, which refers to actions where students organized or
participated in events and community efforts. Common examples of participatory actions
included participating in fund-raisings and volunteering for different organizations.
26
Students participated in such actions to raise-awareness and help others, as well as to learn
how to successfully carry out such projects and to get to know new people.
Additionally, the study found that students are taking steps to make the world a better
place in the future (i.e. preparing for the future). For instance, students were studying hard
in order to get a certain degree or job they saw as beneficial to society (e.g. medical doctor
or engineer), and they were networking with peers and experts. The rationale that students
presented for their future oriented actions were that they believed that development in
science and technology would be the most efficient way to make a positive impact on the
environment.
5.2.3 Summary
The aim of this study was to find out what 15-19 year-old students interested in
science and sustainable development are doing to make the world a better place. The
analysis focused on students’ behaviour, as well as their intentions and motivations for
their actions. Three categories emerged from the analysis, showing that students take
personally responsible actions, participatory actions and actions that prepare them for the
future. Most students were involved in more than one of these actions (see table 2 in
Study III).
According to this study, students see themselves as future citizens or citizens-in-the-
making, but also as citizens of today, who are actively participating in making the world a
better place. This view is slightly different than the views presented previously, where
young students are mainly perceived as future citizens (e.g. Alderson, 2000; Levinson,
2010). The findings of this study also have resemblance to a study conducted by
Westhemer and Kahne (2004), in which they highlight different types of citizenships from
an educational perspective. However, the difference is that this study describes how
students actually behave as citizens, both in and out of the school environment (See Study
III for more discussion on the differences).
5.3. Students’ Expectations of Non-Formal Education within a
Context of Sustainable Development
Previous research has shown that an ideal learning environment for gifted students
supports holistic learning (Tirri, 2011; Tirri, 2012), meaning it supports their academic,
social and emotional needs (Tirri, Kuusisto, & Aksela, 2013). Gifted education should
also be provided with an advanced curriculum (Colangelo et al., 2004) that reflects
students’ interests (Subotnik et al., 2011) and gives them the possibility to advance in their
learning at a faster pace (Colangelo et al., 2004).
To contribute to the discussion on what gifted students expect from their education,
this section presents Study IV(a), which analyses the type of expectations students have
when applying for a non-formal educational program that focuses on sustainable
development from a science, technology, engineering and math (STEM) perspective.
27
This section will first present how the data for the study was collected and analyzed;
and then present the key results and give a summary of the findings.
5.3.1 Data collection and analysis
For the benefit of the reader, in this thesis, Study IV is divided into two parts. The first
part, referred to as Study IV(a), analyzed what type of expectations students have when
applying to an international non-formal educational program. The data for this section of
the study was collected during the first stage of students applying to the 2010-2011
Millennium Youth Camp (see beginning of Chapter). The 1 935 applicants presented a
total of 4 348 open ended expectations for the camp, which were grouped through
qualitative content analysis by the first author of the study. Inter-rater reliability of the
grouping was tested by having an outside researcher analyze a hundred of the expectations
and categorize them into formed groups using the group descriptions created by the first
author. The inter-rater reliability was calculated using Formula 1 (see section 4.1.1) and
was found to be good (ir=0.83). The second part of the study, referred to as Study IV(b),
analyzed how the students’ academic, social and ethical expectations were met and will be
described in section 4.4.
5.3.2 Results
The results of Study IV(a) show that when applying to a science non-formal
educational program most students have academic (90%) and social (68%) expectations
and over a third (38%) of the students have ethical expectations.
Students’ academic expectations focus on wanting to learn more to satisfy their
curiosity in science and to succeed in school. Students also expected to learn skills for
doing their own research. Some students also wanted to know more about the Finnish
academic system and compare it to that of their home countries’. Students’ social
expectations focus on wanting to meet new people from different parts of the world, share
ideas with like-minded youth and make new friends. Some of the students also expected to
get to meet and talk to renowned scientists. Ethical expectations showed that students
wanted to learn how they can make a difference in the world and influence others to do so
as well. These expectations also showed that students want to learn more, in order to be
able to make a difference in the future.
One-fourth (24%) of the students asked both societal and ethical questions. As these
questions were related to each other, a composite variable, called socio-ethical
expectations, was formulated. These expectations typically focused on finding a group of
peers from the camp, who would be interested in working together on an ethical project,
such as raising awareness on climate change.
28
5.3.3 Summary
The aim of this study was to find out what type of expectations students have when
applying to a non-formal educational program interested in science. Study IV(a) found
that students have many academic, social and moral expectations. They want to attend
non-formal education to satisfy their curiosity as well as to make new friends and
participate in meaningful (ethical) discussions. The results coinside with previous
findings, although differences are also discussed in the paper.
5.4. Non-Formal Education Meeting Students’ Needs and
Expectations
As was highlighted in the previous section, gifted students have high expectations
from their education in general and non-formal education in specific. This chapter
presents three studies that aim to answer the fourth research question: How non-formal
education is meeting students’ needs and expectations?
First, Study IV(b) continues from where the previous section left off, by presenting
how project works assigned by specialists contributed to meeting students’ needs. Study
V examines how well non-formal education meets the expectations for relevant education.
Study VI then examines students’ experience of the camp to find out how well the
program meets their expectations.
Similar to the previous sections, this section also consists of three parts. The first part
introduces the way the data for the three studies was collected and analyzed. It also
presents the goals of the camp, used in the analysis of Study IV(b) and V. The second part
discusses the main results of the studies and the final part summarizes the key findings.
5.4.1 Data collection and analysis
Study V examines the relevance of three different non-formal educational programs,
one of these programs being the Millennium Youth Camp. To analyze the relevance of the
camp, the study examined the relevance of the general goals of the camp as well as the
goals set for the project work.
The general goals of the camp were:
x Encourage 1619 year olds to study mathematics, natural sciences, and
technology,
x Introduce students to the academic and professional opportunities that Finland has
to offer in the areas of mathematics, natural sciences and technology, as well as
help strengthen the image of Finland as a great country in which to come to study
and work,
x Make the Millennium Technology Prize better known,
29
x Help the youth network with each other
x Provide students with opportunities to meet researchers and stakeholders in
Finnish companies and organizations, and
x Provide the youth the opportunity to have fun with like-minded youth and enjoy
their experience in Finland.
The goals for the project work were:
x The projects are related to sustainable development,
x There should be more than one right answer to the research question,
x The projects should encourage students to think creatively, and
x The projects should deal with an ongoing discussion between science and society.
Each goal was categorized into one of the three dimensions of relevance (individual,
societal and vocational) by two researchers. The categorization of the researchers were
then compared and it was found that eight of the ten goals were categorized into the same
dimension of relevance (ir=0.80) (see Formula 1). The researchers then discussed the
discrepancies in the analysis and agreed that not enough information was provided on the
two goals they had categorized into different groups. Through the discussion they realized
that the categorization of these two goals depends on whether the goal is viewed from a
students’ point of view or from society’s point of view.
In Study IV(b) five specialists working at the Millennium Youth Camp filled out an
online questionnaire on how well they felt they were able to implement the goals of the
camp curriculum into their coaching. The questionnaire included questions on which and
how curriculum goals had been implemented. The specialists were also asked to describe
additional goals they had set, if they had done so. The specialists gave specific examples
for each of the questions in the questionnaire. In the pre-analysis of the data, two
researchers individually drew out themes that were present in the answers of the
specialists. The reliability of the derived themes was then discussed by the two researchers
and some themes were dropped, while others emphasized until the two researchers found a
mutual agreement on the themes.
In Study VI a questionnaire was given to the attendees of the Millennium Youth Camp
immediately after the camp (part A) and one year after attending the camp (part B). The
data for part A was collected after the 2010-2012 camps. All the participants of the camps
(n=88) answered the questionnaire. In the questionnaire, the participants were asked to
write about the highlights and the areas of improvement of the camp. These open-ended
answers were analyzed by content analysis and the inter-rater reliability of the groups was
tested using Kohen’s Kappa analysis (see Formula 2). The inter-rater reliability was found
to be excellent (N=0.94). In part B, students of the 2010-2011 camps were asked to write
an essay about their camp experience one year after the camp. Half of the campers (n=30)
wrote and submitted the essay. Researchers analyzed these essays to find out what kind of
long-term effects the camp had on the attendees. Content analysis revealed eleven distinct
long term effects. The descriptions of these effects were given to the authors of the essays.
The authors were then asked to analyze which of these effects they find in the essays they
had written. The level of agreement between the authors and the researchers were
30
analyzed using Cohen’s Kappa analysis, and the agreement was found to be excellent
(N=0.91).
5.4.2 Results
The results of Study IV(b) show that the specialists were able to implement different
types of academic goals into the camp. The specialists all agreed that the camp provided a
chance for students to increase their knowledge in science. Furthermore, some of the
specialists mentioned that the camp gave students the opportunity for creative thinking,
learning about academic and professional opportunities, and gaining new experiences in
STEM subjects. The specialists also found that the camp curriculum met the social goals
set for the camp. They found that the camp helped students network with each other, meet
experts and have fun with each other. Also, some of the specialists noted that although
they did not see much of the social activity taking place during the camp, they noticed that
the students were connecting well with each other. During the project works, guided by
the specialists, four out of five of the groups also got to deal with ethical issues, namely
through socio-scientific discussions. This was accomplished by careful selection of the
topic of the project, as well as the specialists leading conversations towards socio-
scientific issues. The specialists also mentioned that many of the groups had the
opportunity to deal with ethical issues while discussing environmental aspects of their
projects.
The results of Study V showed that the ten goals set for the Millennium Youth Camp
contain all three dimensions of relevance. The two researchers agreed that individual
relevance was most strongly present in the goals of the camp. They saw the camp
contributing to student’s individual relevance by helping youth network with one another,
having fun with like-minded youth, presenting research problems that do not have a single
right answer and by giving students’ projects that encourage creative thinking.
Furthermore, projects that deal with sustainable development and socio-scientific issues
add to students’ societal relevance.
Vocational relevance was provided by introducing future academic and professional
opportunities and giving students the opportunity to network with science experts.
Alhough the researchers initially disagreed to what area of relevance two of the goals
contribute to, after discussing the goals, the researchers agreed that the goals can be
categorized into two areas of relevance, depending on the point of view. The two goals
which were more thoroughly discussed were encouraging students to study STEM subjects
and making the Millennium Technology Prize more known. These can be seen to
contribute to societal and/or vocational relevance, depending on whether they are viewed
from the perspective of the student or society.
The results of Study VI(a) showed that student’s expectations of the camp were met as
they enjoyed a wide range of social and academic activity during the Millennium Youth
Camp. The students enjoyed the possibility of getting to know like-minded people
interested and gifted in science. They were especially glad that the camp program gave
them the opportunity to get to familiarize each other with their backgrounds and cultures.
31
In addition, campers enjoyed meeting and discussing science with experts. They found
these encounters inspiring and motivating. The students also enjoyed other social
activities, such as the sauna nights, touring the city and the welcome party, but these were
not highlighted as strongly as the activities that gave students more meaningful encounters
with others.
The results also showed that students interested in science like a wide range of
academic activities. Students especially enjoyed visiting universities, where they could
visit laboratories, talk to experts and work on their projects. Students also enjoyed visiting
companies, which provided similar activities as did the universities. In addition to these,
students mentioned a wide range of other academic activities they enjoyed. The diversity
of activities enjoyed shows the diversity of students, which should always be taken into
consideration when planning a non-formal program for students.
Study VI (b) showed that meeting the students’ expectations impacted their lives well
into the future. The greatest impact (87% of students) was in the way that students saw
themselves and the world around them. For instance, students mentioned that the camp
had increased their motivation and self-confidence. The camp also opened students’ eyes
to see the world around with a wider perspective, and all the possibilities that this offers.
These changes in perspective, also had an academic impact on the students, as their view
on education and their future had changed. A few even mentioned that attending the camp
had a direct effect on them getting into a school or being accepted to an internship. Even a
year after the camp, students continued keeping in touch with other camp participants,
feeling that the camp had met their social expectations, as it had provided them with
friends from all parts of the world. Some even said that it was the first time they felt
appreciated for the things for which they had a passion.
5.4.3 Summary
The three studies presented in this section aimed to find out how non-formal education
can be made relevant to meet the students’ needs. Study IV showed that a variety of
educational goals meeting the three dimensions of relevance can be implemented into
projects that are given to the students. These projects should be centered on students’
interests. Study V showed that by having sustainable development as a context in a non-
formal educational program, the goal will meet expectations of societal relevance.
Individual and vocational relevance can also easily be implemented into non-formal
education. Study VI discussed the different academic and social activities that students
find to be a meaningful part of non-formal education. Combined, the three studies give
useful insight on how non-formal education can meet the needs and expectations of
students.
32
33
6. VALIDITY AND RELIABILITY
This chapter discusses the validity and the reliability of this thesis by examining the
research approaches and methods used. Some of this discussion has already been
embedded into the previous two Chapters, so the main focus of this chapter is to examine
how well the selected research approaches answer the research questions, and hence, the
research problem, despite the methodological limitations that were presented in Chapter 4
and Studies I-VI.
It is clear that every research method and approach will have its limitations. Therefore,
it is crucial to examine how well the research has answered the research problem and
whether the same results would be obtained if the experiments would be repeated.
Discussion of the validity and reliability of this research are used to examine this.
Validity refers to how accurately a study is able to measure what it has set out to
measure (Cohen et al., 2008). Validity can be divided into external and internal validity.
External validity refers to how well the results of a study are able to be generalized or
transferred, whereas internal validity refers to how vigorously a study is conducted, how
well the data supports the discussion and how well alternative explanations for the results
are taken into consideration (Cohen et al., 2008).
To discuss the external validity of this thesis, scrutiny is needed of the specific
methodologies chosen. Many qualitative studies are not conducted to provide
generalizations, but rather to provide transferability. Such is the case in this thesis. Data
collected from students who are gifted in science cannot be generalized to students in a
regular classroom; nor can the questions asked by students who are interested in science
and sustainable development. Therefore, due to the qualitative nature of this thesis, most
of the data is not directly generazible to classrooms. However, due to the multiple methods
used in collecting and analyzing the data, the results are generalizable to other similar
groups of students, namely gifted students or students interested in science. Furthermore,
the data is transferable to classroom settings, as any given classroom will typically have
students who are gifted in science or interested in sustainable development. The
transferability is further increased by using a mixture of descriptive research
methodologies and case studies. For instance, in this thesis, descriptive research gives a
broad perspective on how students’ expectations for non-formal education were met,
whereas the case studies look more into the intricate details of the same issue.
The internal validity of the thesis was enhanced through several means. First, the
studies were conducted over several years from a relatively large number of participants.
Some of the studies also consisted of longitudinal research. Furthermore, the methods
used to collect and analyze the data have been described in detail in Studies I-VI, bringing
clarification to the research approaches used. When combined, these factors increase the
internal validity of the research, as they highlight that the studies were designed with care
and transparency.
The validity of the content also affect the validity of the thesis. In the studies presented
in this thesis, content validity was increased by collecting data anonymously from the
students (when possible) and by not telling them the research interests of the researchers.
This was done in order to avoid students from answering questions the way they thought
34
the researchers would want them to be answered. However, it is reasonable to say that this
could not be avoided completely. First, the students applying to the camp may have
presented certain types of questions to impress the reader. Secondly, the interviewed
students may have tried to impress the researchers with saying they take environmentally
friendly actions, whereas in reality, their actions may have only been environmentally
friendly behavior (see Jensen & Schnack, 1997). Due to the nature of the methodologies
used in this thesis, it has been necessary to assume that the participants are honest in their
answers. This same assumption applies to most research in education and social sciences.
The way to overcome this challenge would be to conduct observational research (e.g.
ethnographic research), but such research would have not been the most efficient way to
answer the research questions of this thesis. To reduce the possibility of students being
dishonest, content validity was increased by collecting data over time (time triangulation)
and by collecting data from a large sample of students.
In addition to validity, a well conducted research needs to examine the reliability of
the results. This means that the extent to which experiments can be repeated to obtain the
same results needs to be considered (Cohen et al., 2008). In this thesis, the reliability was
assured though a number of ways. The first factor influencing the reliability of this thesis
is that the data was collected over a period of time, and the data collected from different
years pointing towards the same results and conclusions. Furthermore, the thesis used
different ways to examine the same research question. This is seen in RQ1, in which two
distinct ways of analyzing the students questions on sustainable development and climate
change still show that there is resemblance in the results. Different research methods were
also used to examine RQ4, all methods pointing to the same conclusions.
Most importantly, the reliability of the studies presented in this thesis was increased by
inter-rater reliability, which was used in several ways, as seen in Chapter 5. Using peer
assessment on the analysis gives confidence that the data was categorized in a reliable way
and that the data analysis could be replicated in future research as well. Furthermore, inter-
rater reliability helps overcome some of the limitations of case studies, namely, the
subjectivity of the results (Cohen et al., 2008).
To conclude, this thesis has overcome many of the common challenges related to
validity and the reliability by using triangulation and a mixed methods approach. As with
all qualitative research, generalizations of the findings must be made with care, but the
transferability of the findings are on a solid foundation. Furthermore, this chapter gives
sufficient arguments and examples to claim that the internal validity of the research has
been considered extensively. Through out the research, sufficient measures have also been
taken to ensure that the content used is valid. Finally, the reliability of the findings has
been examined from multiple perspectives and the inter-rater reliability has been checked
in all of the studies. In sum, this thesis has considered multiple aspects of validity and
reliability providing a foundation that the data and the results of this thesis are trustworthy.
35
7. DISCUSSION AND CONCLUSIONS
This thesis examines the multifaceted research problem of “what do international
youth find relevant in sustainable development and its education”. This research
problem was examined using several research methodologies, namely descriptive
research, case studies and elements of grounded theory.
The research problem was set on the assumption that students do not find science
education to be relevant (see e.g. Hofstein et al., 2011; Osborne & Dillon, 2008), and that
sustainable development, with its multidisciplinary issues, has the potential to bring
relevance to science education (e.g. de Haan, 2006). It also acknowledges that earlier
research on students’ perspectives on sustainable development and its education are
lacking. Using this knowledge as a baseline, this thesis set out to examine students’
perspectives on sustainable development, in order to contribute to the discussion on how
ESD could be used to make science education more relevant.
As mentioned in the introduction, answering the multifaceted research problem is not a
simple task. One reason is that ‘relevance’ can be understood in many ways, as has been
discussed by Stuckey et al., (2013). Relevance can depend on a students’ motivation and
interest towards the topic, the relevance of the topic to society now and in the future, and
the understanding of how knowledge about the topic will help students make decisions as
future employees and citizens (see Stuckey et al., 2013). Though not the only solution to
the problem, Eilks and Hofstein (2014) have discussed how bringing ESD into chemistry
education can provide individual, societal and vocational relevance to the students. For
this reason, this thesis examines students’ perspective on the issue in order to provide a
deeper understanding of what possibilities ESD can provide. Furthermore, this thesis
relates the discussion to different educational approaches, with the aim to make education
holistic, taking into consideration students academic, social and emotional needs (see
Tirri et al., 2013).
This thesis contributes to answering the research problem through four research
questions related to the issue. RQ1, RQ2 and RQ3 focus primarily on giving a picture of
students’ perspective on ESD, whereas RQ4 focuses more on providing a model on how
students’ needs could be met.
7.1. Students’ Questions on Sustainable Development
The findings from the first research question “what type of questions do students
ask about sustainable development?” shows that when dealing with sustainable
development, students want science education to provide a societal and ethical
perspective, in addition to the more common academic perspective. The importance of
discussing societal and moral issues in science education has already been emphasized by
many educational researchers (e.g.(Burmeister & Eilks, 2012; Hodson, 2008; Juntunen &
Aksela, 2014; Ratcliffe & Grace, 2003), but from the two studies presented here, it is seen
that dealing with sustainable development from a holistic point of view is especially
36
important for the students. It is also note-worthy that students want to learn more about
issues, such as the trust-worthiness of the media and scientific research, giving further
support that socio-scientific issues and the nature of science should be discussed to make
science education more relevant for the students.
As students show interest in wanting to learn more about complex societal and moral
issues in a science context, the findings imply that even if education were to move further
towards a student-centered approach, many of the important societal and moral aspects of
sustainable development would be addressed by the students. Maybe even more so, as
teachers may be incompetent to teach such issues (e.g.Ocal et al., 2011; Papadimitriou,
2004). Their teaching may be affected by their own world view (Lombardi & Sinatra,
2013). Furthermore, allowing students to address their own questions could help the
students stay motivated (see Pedersen & Liu, 2003), as they find the questions to be
important. This can also increase students’ life-long learning skills and critical thinking
skills (see Cornelius-White, 2007),
From a teachers perspective, understanding the type of questions students ask can help
the teacher address the students’ interests and give greater understanding to their stage of
development, thus, helping teachers differentiate students based on their interests.
Expectedly, this should have a positive impact on the students’ individual relevance.
However, it is important to note that the findings here may give a biased view on the
type of questions asked in a typical classroom on a topic related to sustainable
development. The reason for this is that the data in this study was collected from students
interested in sustainable development and climate change. Due to their interest, they have
most likely studied the issues in more detail than other students, and therefore, ask very
diverse questions. However, this does not mean that these results are irrelevant to
classroom practice. On the contrary, understanding the diversity of questions that students
may be interested in helps the teacher moderate classroom discussion and guide the
conversation towards the topics that have not yet been discussed. Guided discussions may
even help students realize the topics they are interested in, but have not been able to
articulate. Unfortunately, due to the nature of the studies here, this thesis is only able to
give a hypothesis on how student-centered education could be incorporated into classroom
practice and acknowledges that further practical research is needed.
To conclude, Studies I and II imply that it is reasonable to further examine the
possibilities of student-centered education that stems from students’ questions. Pre-service
and in-service teacher training should focus on providing teachers with the tools to use
students’ questions to start relevant discussions and project works. Furthermore, teachers
should be made aware that, as the topics are multidisciplinary, they may be incapable of
answering all of the students’ questions on sustainable development. However, this can be
overcome by using various pedagogical methods been discussed in this thesis.
7.1. Students’ Actions
The second research question, “What type of actions do students take to make the
world a better place?” builds on the rationale that action competence is an important
37
aspect of ESD (e.g. Mogensen & Schnack, 2010), and more generally, citizenship
education (Hitchcock & Hughes, 1995). As educators understand the type of actions
students’ are already taking, they can use that knowledge as a way to approach issues on
sustainable development. Furthermore, by building on students’ experiences and making a
connection to their everyday lives, education can be made more relevant (see Stuckey et
al., 2013).
Since students see themselves as citizens of today and the future (see 4.2.3), education
should focus on what a citizen can and should do to take action on important issues. The
context of sustainable development presents many such important issues which require
action from citizens. However, if only certain beneficial actions are presented to the
students, this may not increase action competence, but rather, would be a behavioral
change (see Jensen & Schnack, 1997). Therefore, it could be more beneficial to build on
the actions in which the students are already engaged. For instance, students could
evaluate their actions from an environmental, societal and economical perspective and
analyze what type of actions would be most beneficial. Such discussions among students
or with a teacher could increase students’ critical thinking skills, as well as self-awareness
(Cornelius-White, 2007). Furthermore, education could provide students with more
opportunities to take action by allowing them to plan and execute different types of actions
with peers and experts, for instance, in a non-formal education context. Though such an
approach does provide many benefits, the danger is that ESD becomes too centered on a
single action, even though it should be holistic. Therefore, concentrating on students’
actions should only be seen as one means to bring relevant ESD into learning.
Another way to incorporate students’ actions into ESD is to take action competence
into consideration in student assessment. For instance, when taking part in different
projects in informal or non-formal settings, students are constantly learning about a topic.
The knowledge and experience gained are relevant for the students, but a traditional
educational system does not take such learning into consideration in the assessment of the
students, even though they might be very meaningful to their future lives and careers (see
Study VI). Of course, assessing action competence is challenging, as there isn’t any
“right actions”, just as there are no “right answers” to socio-scientific issues (e.g. Abd-El-
Khalick, 2003; Ratcliffe & Grace, 2003). However, some tools do already exist on how
action competence could be assessed (Wood, 2015) and how future research should
concentrate on creating more useful tools for a science education context.
The findings of Study III are compelling in that they show that students actively take
action and by so doing, show action competence. These findings seem to be an anomaly,
as previous research has shown that students are not usually willing to take action, even
though they see an action as the morally right thing to do (Sternang & Lundholm, 2011).
Therefore, future research should look deeper into why certain students are more willing
to take actions than others. Previous research has shown that gifted students tend to have a
higher level of moral judgment than their peers (Narváez, 1993), this being a possible
reason for the anomaly, though most likely, not the only reason.
38
7.2.1 Action Competence
One of the main challenges in ESD is to empower students (Juntunen & Aksela, 2014)
and to help them become action competent. Previous studies on the issue have described
what action competence is and is not, but the problem on how to achieve action
competence remains. One issue with action competence is that it is often seen as a state
that a student either has or has not achieved. However, examining the results of Study III
show that drawing a line in what is and what is not action competence is challenging.
Challenges in drawing this line are also seen in the need for extensive explanations on
what action competence is, written by Jensen and Schnack (1997).
Rather than seeing action competence at a state that can be reached, it would be more
beneficial to consider it as an ongoing process - a skill that can be developed. Therefore,
especially for educational purposes it is beneficial to consider how this development
happens. A suggestion for such a model is presented in Figure 4 and explained below.
Figure 4. A model on how to develop students’ action competence (applied from
Juntunen & Aksela, 2014; Jensen & Schnack, 1997)
1. Find a problem: Students find an environmental problem that affects their immediate
community (e.g. air quality) or is a global environmental problem (e.g. climate
change). In Study III, most students have already done this, but this may not be the
case in a typical classroom.
2. Develop action: Students then brainstorm different types of actions that could be
taken in order to contribute to solving this environmental problem.
3. Take Action: Students choose one or more action that they wish to take to mitigate the
environmental problem. As Study III shows, students will take a variety of different
types of actions, with varying impact on the environment.
4. Analyze action: Critical thinking is a central element of developing action
competence (Mogensen, 1997). Therefore, students need to critically analyze the
actions they are taking. For instance, students could analyze the environmental,
39
societal and economic impact of their actions. To do such an analysis, the students
need to study issues related to a problem, such as looking at a products environmental
impact and life-cycle. The depth of the analysis should be determined by the learning
goals and the students’ competence. The goal of the analysis should be to pinpoint
shortcomings or discrepancies in the action. In an ESD context this could mean
realizing that the paper bags that a student has started using may, in fact, be more
harmful to the environment than plastic bags. Especially the analysis and further
development of actions is what differentiates actions from mere behavior (see Jensen
& Schnack, 1997).
5. Find a (new) problem: If students don’t find any significant areas of improvement in
their previous actions, they should be encouraged to keep doing what they are doing
and find a new problem that they also start to solve.
6. Develop action (further): If students have found that their action doesn’t have a big
impact in helping to solve the environmental issue in hand, they should develop their
action further, or come up with new actions to solve the problem and then again, test
out these actions.
If this process is to be taught in a class-room setting, the studies presented in this thesis
suggest that students should receive social support and feedback from peers and the
teacher to encourage them in the pursuit. Getting other people involved in the endeavors
will also help the student stay focused in developing their actions.
7.3. Students’ Expectations of Non-Formal Education
The findings from the third research question, “What type of expectations do
students have for non-formal education with a context of sustainable development?”
coinside with the findings presented in the previous sections as the findings clearly show
that in addition to their academic expectations, students also expect meaningful social
interaction and the possibility to participate in ethical discussions.
The key expectations from a non-formal education program are similar to the
expectations gifted students have about formal education, namely, an advanced academic
content (Colangelo et al., 2004) that reflects their interests (Subotnik et al., 2011). A
deeper analysis also shows that students expect to be given possibilities to do their own
research projects, either through literature reviews or field experiments, as well as learn
about the nature of science. The underlying goal, therefore, seems to be to gain a holistic
view of science, especially crucial in a sustainable development context.
This implies that students want non-formal education to focus on vocational relevance,
not only through gaining more knowledge, but also gaining understanding in how research
is done and how the research community operates. To achieve this goal, interactions with
the science community are important. In relation to a formal school setting, the findings
imply that students should be given more opportunities to plan and execute their own
40
research projects. Furthermore, setting up a “science community” in the classroom, where
students review and critique each other’s work, could be beneficial, though should not be
used to replace encounters with the real science community (e.g. through company visits).
The expectations of the students also show that education should provide students with the
understanding on how political and financial aspects play a part in what type of research is
conducted (see Hodson, 2008 for more discussion on NOS).
Furthermore, this study emphasized the importance of social relationships. Previous
research has indicated that social aspects are an important part of education, as they can
motivate students and affect their view on education (e.g. Bliuc et al., 2011; Tirri &
Kuusisto, 2013). However, as seen in this study, students also want to be surrounded by a
social network so that they can learn from their peers and collaborate with them. Students
see international collaboration as especially beneficial when dealing with sustainability
issues.
The findings show that students are keen to share their own experiences on sustainable
development, as well as to hear how other countries deal with sustainability issues.
Alhough the significance of exchanging ideas with international peers is not studied in this
thesis, a reasonable hypothesis is that such encounters increase self-awareness on the
topic, further increasing action competence. Furthermore, discussion on national policies
towards sustainability can increase understanding on societal relevance. Therefore, based
on the results, when dealing with sustainable development, international collaboration
between schools should be developed in formal education, as well.
The results of Study III also indicate that gifted students are aware that sustainability
issues are multifaceted, as is seen in their high expectations for ethical discussions.
However, the expectations imply that at least some students want to know what is right
and what is wrong. Dealing with issues related to sustainable development provides the
platform to discuss how there may not be a right or wrong answer to certain questions, but
rather, the answer depends on the interests of the person who is asked. Mixed interests and
the challenges of evaluating certain scientific processes or products as good or bad are
well presented in a research conducted by Burmeister and Eilks (2012), which analyzes
the environmental, economic and practical benefits of different plastics.
7.4. Meeting Students’ Needs and Expectations through Non-
Formal Education
As was presented in the previous sections, students have a wide range of expectations
regarding heir education, ranging from academic, societal, social and ethical aspects. This
section discusses how non-formal education can work as a means to meet these
expectations.
Previous studies have already shown that non-formal education has many positive
effects, such as increasing students’ interest in science (E. Pedretti, 2002), as the students
build meaningful social relationships (Rahm, 2004) and work with themes that are of
interest to them. The studies presented in this section contribute to the discussion on the
importance of non-formal education by: (i) showing that non-formal education can address
41
all three dimensions of relevance (Study V), (ii) discussing how specialists working at the
camp are able to meet different dimensions of relevant education (Study IV), and (iii)
addressing how non-formal education can meet students’ academic, social and
ethical/emotional expectations (Study VI).
First, Study V shows that creating a camp curriculum around the students’ needs and
expectations provides all three dimensions of relevance in a fairly balanced way. As is
seen through the other studies presented, many of the students attending the camp have
personal interest towards science, and more specifically sustainable development. They
have previously worked on personal projects, and have taken actions to mitigate
environmental problems. Providing individual relevance in non-formal education, will
resonate with these previous projects and experiences. Study V also discusses how the
camp curriculum provides societal relevance. Here a context of sustainable development is
apparent, as it helps create the link between science and society. Societal relevance is
something that is commonly overlooked in science education (Eilks & Hofstein, 2014),
but a clear focus on sustainable development could help overcome this. Study V shows
how the curriculum uses a network of scientists and facilities to provide vocational
relevance. Providing students with mentors and role-models may help them decide a
career path, and so, this opportunity should be provided in non-formal, as well as formal
education if more scientists are to be recruited.
Study IV shows how non-formal education provides a great platform to deal with
timely issues through projects that focus on knowledge increase, creative thinking,
learning about academic and professional opportunities, peer interaction and discourse on
ethical issues. The study also shows that when sustainable development is set as a goal for
an educational program, specialists will find ways to incorporate a multidisciplinary
approach to the scientific issues that are dealt with. The specialists noticed that when they
did so, students had courage to discuss ethical issues related to the scientific topics. Some
specialists noted that these discussions happened spontaneously among the students and
that the students also had courage to ask ethical questions from experts from universities
and representatives of companies. Encountering such discussion could partly be because
gifted students tend to have high moral sensitivity (Gowda, Fox, & Magelky, 1997). It is
also reasonable to assume that the camp environment, with its diverse social activities and
creative projects, gave students more courage to ask questions on controversial issues. The
reason to assume so is that earlier research has shown that culture and environemt affect
self-expression (Kim & Sherman, 2007). Providing an encouraging environment for self-
expression will also make sharing ethical views possible.
Though several of the specialists working at the camp were able to actualize ethical
goals, the results do indicate that they were harder to incorporate than academic and social
goals. Based on the results it seems that some of the specialists did not see the importance
of implementing the ethical issues, or they found it hard to incorporate them into the
project. This can also be the case in formal education: Issues related to sustainable
development may be seen as important, but not important enough to change the content of
the curriculum or the pedagogical methods used. Dealing with such complex issues can be
challenging for a teacher, as they need to change their role from information giver to
facilitator. Furthermore, they may not want to give up the integrity of their subject
42
(Gayford, 2002). Therefore, helping pre-service and in-service teachers understand that
they are not only teaching the science knowledge of a subject, but rather, are involved in
citizenship education, may help change their perception. Furthermore, teacher training
should focus on how to change roles from an information provider to that of a facilitator.
Furthermore, more research is needed on why teachers select the pedagogical methods that
they do, even though they may not meet the learning goals they have in mind.
Study VI gives further insight on how the students’ academic, social and ethical needs
can be met through non-formal education by discussing the meaningful interactions that
take place during the non-formal program. As was already seen in the expectations,
students want to work in an international atmosphere, where they can share ideas with
people from different parts of the world. The Millennium Youth Camp provided this
opportunity by having an international evening, where students learned about each other’s
countries and cultures. Moreover, the working groups consisted of students from many
different nations, making the groups highly international. Meeting students from different
parts of the world also increased the individual relevance of the projects, as students
realized the different impacts that environmental issues such as climate change, may have
on their friends living in different parts of the world.
The expectations also showed that students want to discuss science related topics with
experts and peers. This opportunity was provided by having specialists guide the group
projects and by making them easily available throughout the week long camp. As the
students became familiar with the experts during the camp, they felt more comfortable
asking hard questions and talking about ethical issues.
The longitudinal study (in Study VI) showed that non-formal educational programs
can become meaningful events in a students’ life, inspiring them and providing them with
more self-confidence. However, as some other researchers argue that non-formal
educational programs are not necessary for gifted students to achieve well (Hany &
Grosch, 2007), further research on the topic should be made. Regarding educational
reform, it would be especially valuable to know the type of elements of which a
meaningful encounter consist, and how these elements can be enforced in education to
make it more relevant for the students.
7.5. Implications
This thesis sought to examine ways to make science education more relevant. The
findings show that students want education for sustainable development to consist of
academic, societal, social and ethical aspects. In other words, students want education to
be holistic.
The students’ questions imply that if students were given more freedom to focus on the
sustainability issues they are interested in, they would examine the issue from a scientific,
societal and ethical perspective. Students’ actions are also multifaceted, showing that they
have a level of action competence. In order to address students’ questions and help them
develop their action competence, new pedagogical approaches are needed. Some
suggestions are presented in this thesis, but still need to be tested in practice. The vast
43
array of students’ questions and actions show that there is much that can be incorporated
into student-centered education. However, pre-service and in-service teacher training in
student-centered learning approaches are needed.
The thesis also gives implications on how non-formal education could address some of
the educational needs. For instance, non-formal education could provide the platform for
students to work on their own project under the support of specialists. Furthermore, non-
formal education can provide meaningful encounters in an international community with
both peers and experts. The thesis also implies that some social programs are more
effective than others in helping students meet their social and ethical needs. In essence, the
findings give suggestions on what aspects should be incorporated to non-formal education
in order to provide a holistic learning environment where students’ academic, societal,
social and ethical needs are met.
44
45
REFERENCES
A31. (2006). A31: UN coorporated. Retrieved from http://aseed.net/uncorporated/a31-
materials.htm
Abd-El-Khalick, F. (2003). Socioscientific issues in pre-collage science classroom. In D.
L. Zeidler (Ed.), The role of moral reasoning on socioscientific issues and discourse
in science education (pp. 41-61). Netherlands: Kluwer Academic Publishiers.
Aksela, M., & Karjalainen, V. (2008). Kemian opetus tänään: Nykytila ja haasteet
suomessa. >Chemistry education today: Current state and challenges in Finland@
Helsingin Yliopisto: Kemian opetuksen keskus.
Alderson, P. (2000). Citizenship in theory and practice: Being or becoming citizens with
rights. In D. Lawton, J. Cairns, R Gardner (Eds.), Education for Citizenship (pp. 114-
135. London: Continuum
Belle, T. J. (1982). Formal, nonformal and informal education: A holistic perspective on
lifelong learning. International Review of Education, 28(2), 159-175.
Best, J. W. (1970). Research in education. Englewood Cliffs, NJ: Prentice Hall.
Bliuc, A., Ellis, R. A., Goodyear, P., & Hendres, D. M. (2011). Understanding student
learning in context: Relationships between university students’ social identity,
approaches to learning, and academic performance European Journal of Psychology
of Education, 26(3), 417-433.
Bryman, A. (2008). Social research methods (8th ed.). New York: Oxford university
press.
Burmeister, M., & Eilks, I. (2012). An example of learning about plastics and their
evaluation as a contribution to education for sustainable development in secondary
school chemistry teaching. Chemistry Education Research and Practice, 13, 93-102.
doi:10.1039/C1RP90067F
Bybee, R. (1987). Science education and the scienceǦtechnologyǦsociety (SǦTǦS) theme.
Science Education, 71(5), 667-683.
Cohen, J. (1960). A coefficient of agreement for nominal scales. Educational and
Psychological Measurement, (20), 37-46.
Cohen, L., Manion, L., & Morrison, K. (2008). Research methods in education (6th ed.).
London: Routledge.
Colangelo, N., Assouline, S., & Gross, M. (Eds.). (2004). A nation deceived: How schools
hold back america's brightest students (1st ed.). Iowa: University of Iowa.
46
Commoner, B. (1972). A bulletin dialogue on" the closing circle," response. Bulletin of the
Atomic Scientists, 28(5), 42-56.
Cornelius-White, J. (2007). Learner-centered teacher-student relationships are effective: A
meta-analysis. Review of Educational Research, 77(1), 113-143.
De Haan, G. (2006). The BLK ‘21’ programme in Germany: A
‘Gestaltungskompetenz’Ǧbased model for education for sustainable development.
Environmental Education Research, 12(1), 19-32.
DeBoer, G. E. (2000). Scientific literacy: Another look at its historical and contemporary
meanings and its relationship to science education reform. Journal of Research in
Science Teaching, 37(6), 582-601.
Denscombe, M. (2010). The good research guide for small scale social research projects
(4th ed.). Berkshire: Open University Press.
Dillon, J. (2009). On scientific literacy and curriculum reform. International Journal of
Environmental and Science Education, 4(3), 201-213.
Ehrlich, P. R., & Holdren, J. P. (1971). Impact of population growth. Science, 171, 1212-
1217.
Eilks, I., & Hofstein, A. (2014). Combining the question of the relevance of science
education with the idea of education for sustainable development. In I. Eilks, S.
Markic & B. Ralle (Eds.), Science education research and education for sustainable
development (pp. 3-14). Germany: Shaker Verlag.
Eshach, H. (2007). Bridging in-school and out-of-school learning: Formal, non-formal,
and informal education Journal of Science Education and Technology, 16(2), 171-
190.
Estes, C. A. (2004). Promoting student-centered learning in experiential education.
Journal of Experiential Education, 27(2), 141-160.
Finland's Science Education Centre. (2012). Millennium youth camp. Retrieved from
http://www.helsinki.fi/luma/english/millennium-youth-camp on 6/2014.
Gayford, C. (2002). Controversial environmental issues: A case study for the professional
development of science teachers. International Journal of Science Education, 24(11),
1191-1200.
Germann, P. J. (1988). Development of the attitude toward science in school assessment
and its use to investigate the relationship between science achievement and attitude
toward science in school. Journal of Research in Science Teaching, 25(8), 689-703.
Gilbert, J. (2006). On the nature of “Context” in chemical education. International
Journal of Science Education, 28(9), 957-976.
47
Gilbert, J., Bulte, A. M. W., & Pilot, A. (2011). Concept development and transfer in
ContextǦBased science education. International Journal of Science Education, 33(6),
817-837.
Gowda, M. V. R., Fox, J. C., & Magelky, R. D. (1997). Students’ understanding of
climate change: Insights for scientists and educators. Bulletin of the American
Meteorological Society, 78(1), 2232-2240.
Hannafin, M., & Land, S. M. (1997). The foundations and assumptions of technology-
enhanced student-centered learning environments. Instructional Science, 25(3), 167-
202.
Hannafin, M. (1992). Emerging technologies, ISD, and learning environments: Critical
perspectives. Educational Technology Research and Development, 40(1), 49-63.
Hany, E. A., & Grosch, C. (2007). Long-term effects of enrichment summer courses on
the academic performance of gifted adolescents. Educational Research and
Evaluation, 13(6), 521-537.
Hitchcock, G., & Hughes, D. (1995). Research and the teacher (2nd ed.). London:
Routledge.
Hodson, D. (2008). Towards scientific literacy: A teacher's guide to the history,
philosophy and sociology of science. Rotterdam, Neatherlands: Sense Publishers.
Hofstein, A., Eilks, I., & Bybee, R. (2011). Societal issues and their importance for
contemporary science education - a pedagogical justification and the state-of-the-art
in Israel, Germany and the USA. International Journal of Science and Mathematics
Education, 9(6), 1459-1483.
Hopwood, B., Mellor, M., & O'Brien, G. (2005). Sustainable development: Mapping
different approaches. Sustainable Development, 13(1), 38-52.
Hurd, P. D. (1970). Scientific enlightenment for an age of science. The Science Teacher,
37, 13-16.
Hynes, P. (1993). Taking population out of the equation: Reformulating I= PAT. USA:
North Amherst Massachusetts Institute on Women and Technology. Retrieved from
http://www.readingfromtheleft.com/PDF/IPAT-Hynes.pdf on 11/2014.
IPCC. (2014). Summary for policymakers. In Field, C.B., V.R. Barros, D.J. Dokken, K.J.
Mach, M.D. Mastrandrea, T.E. Bilir, M. Chatterjee, K.L. Ebi, Y.O. Estrada, R.C.
Genova, B. Girma, E.S. Kissel, A.N. Levy, S. MacCracken, P.R. Mastrandrea, and
L.L. White (Ed.), Climate change 2014: Impacts, adaptation, and vulnerability. part
A: Global and sectoral aspects. contribution of working group II to the fifth
assessment report of the intergovernmental panel on climate change. (pp. 1-32).
Cambridge, United Kingdom and New York, NY, USA: Cambridge University Press.
48
Jensen, B. B., & Schnack, K. (1997). The action competence approach in environmental
education. Environmental Education Research, 3(2), 163-178.
Johnston, P., Everard, M., Santillo, D., & Robert, K. H. (2007). Reclaiming the definition
of sustainability. Environmental Science and Pollution Research International, 14(1),
60-66.
Jon Hawkes. (2001). The fourth pillar of sustainability: Culture's essential role in public
planning. Australia: Common Ground Publishing.
Jonassen, D. H. (2000). Revisiting activity theory as a framework for designing student-
centered learning environments. In D. H. Jonassen, & S. M. Land (Eds.), Theoretical
foundations of learning environments (pp. 89-121). Mahwah, New Jersey: Lawrence
Erlbaum Associates.
Juntunen, M., & Aksela, M. (2014). Education for sustainable development in chemistry
challenges, possibilities and pedagogical models in Finland and elsewhere. Chemistry
Education Research and Practice, 15(4), 488-500.
Kahneman, D., & Tversky, A. (1979). Prospect theory: An analysis of decision under risk.
Econometrica: Journal of the Econometric Society, 263-291.
Kim, H. S., & Sherman, D. K. (2007). "Express yourself": Culture and the effect of self-
expression on choice. Journal of Personality and Social Psychology, 92(1), 1.
Levinson, R. (2010). Science education and democratic participation: An uneasy
congruence? Studies in Science Education, 46(1), 69-119.
Lombardi, D., & Sinatra, G. M. (2013). Emotions about teaching about human-induced
climate change. International Journal of Science Education, 35(1), 167-191.
Marks, R., & Eilks, I. (2009). Promoting scientific literacy using a sociocritical and
problem-oriented approach to chemistry teaching: Concept, examples, experiences.
International Journal of Environmental and Science Education, 4(3), 231-245.
McKeown, R., Hopkins, C. A., Rizi, R., & Chrystalbridge, M. (2002). Education for
sustainable development toolkit. Knoxville:University of Tennessee.
Meadows, D., Meadows, D., Randers, J., & Behrens, W. (1972). The limits to growth.
New York: Universe Books. Retrieved from http://www.donellameadows.org/wp-
content/userfiles/Limits-to-Growth-digital-scan-version.pdf on 8/2014.
Mischel, W. (1973). Toward a cognitive social learning reconceptualization of personality.
Psychological Review, 80(4), 252.
Mogensen, F. (1997). Critical thinking: A central element in developing action
competence in health and environmental education. Health Education Research,
12(4), 429-436.
49
Mogensen, F., & Schnack, K. (2010). The action competence approach and the ‘new’
discourses of education for sustainable development, competence and quality criteria.
Environmental Education Research, 16(1), 59-74.
Moon, S. M., Feldhusen, J. F., & Dillon, D. R. (1994). Long-term effects of an enrichment
program based on the purdue three-stage model. Gifted Child Quarterly, (38), 38-48.
Moser, S. C., & Dilling, L. (2004). Making climate hot. Environment: Science and Policy
for Sustainable Development, 46(10), 32-46.
Narváez, D. (1993). High-achieving students and moral judgement. Journal for the
Education of the Gifted, 15, 268-279.
Niset, J., & Watt, J. (1984). Case study. In J. Bell, T. Bush, A. Fox, J. Goodey & S.
Goulding (Eds.), Conducting small-scale investigations in educational management
(pp. 79-92). London: Harper and Row.
Ocal, A., Kisoglu, M., Alas, A., & Gurbuz, H. (2011). Turkish prospective teachers’
understanding and misunderstanding on global warming. International Research in
Geographical and Environmental Education, 20(3), 215-226.
Osborne, J., & Dillon, J. (2008). Science education in Europe: Critical reflections.
London: The Nuffield Foundation.
Osborne, J., Simon, S., & Collins, S. (2003). Attitudes towards science: A review of the
literature and its implications International Journal of Science Education, 25(9),
1049-1079.
Paden, M. (2000). Education for sustainability and environmental education. Education
for a sustainable future (pp. 7-13). New York: Springer. Retrieved from
http://link.springer.com/chapter/10.1007/978-1-4615-4277-3_2 on 2/2013.
Papadimitriou, V. (2004). Prospective primary teachers' understanding of climate change,
greenhouse effect, and ozone layer depletion. Journal of Science Education and
Technology, 13(2), 299-307.
Pedersen, S., & Liu, M. (2003). Teacher's beliefs about issues in the implementation of a
student-centered learning environment. Educational Technology Research and
Development, 51(2), 57-76.
Pedretti, E. (2002). T. kuhn meets T. rex: Critical conversations and new directions in
science centres and science museums. Studies in Science Education, 37, 1-42.
Pedretti, E., & Nazir, J. (2011). Currents in STSE education: Mapping a complex field, 40
years on. Science Education, 95(4), 601-626.
Pekel, F. O., & Özay, E. (2005). Turkish high school students' perceptions of ozone layer
depletion. Applied Environmental Education & Communication, 4(2), 115-123.
50
Rahm, J. (2004). Multiple modes of meaning-making in a science center. Science
Education, 88(2), 223-247.
Ratcliffe, M., & Grace, M. (2003). Science education for citizenship: Teaching socio-
scientific issues. Berkshire: McGraw-Hill International.
Rennie, L. J. (1994). Measuring affective outcomes from a visit to a science education
centre Research in Science Education, 24(1), 261-269.
Rhodes, S. (2013). Looking long-term: Do environmental education programs have
lasting impacts on perceptions of nature. Thesis, The Ohio State University, USA.
Richardson, V. (1998). How teachers change: What will lead to change that most benefits
student learning? Focus on Basics: Connecting Research & Practice, 2(C)
Rinn, A. N. (2006). Effects of a summer program on the social self-concepts of gifted
adolescents. Prufrock Journal, 17(2), 65-75.
Robinson, J. (2004). Squaring the circle? Some thoughts on the idea of sustainable
development. Ecological Economics, 48(4), 369-384.
Robson, C. (2002). Real world research (2nd ed.). Blackwell: Oxford.
Rockström, J., Steffen, W., Noone, K., Persson, Å., Chaplin, F. S., Lambin, E. F., &
Foley, J. A. (2009). A safe operating space for humanity. Nature, 461, 472-475.
Sadler, T. D. (2011). Situating socio-scientific issues in classrooms as a means of
achieving goals of science education. Socio-scientific issues in the classroom (pp. 1-
9). Netherlands: Springer.
Schreiner, C., Henriksen, E., Kirkeby, H., & Pål, J. (2005). Climate education:
Empowering today's youth to meet tomorrow's challenges. Studies in Science
Education, 41(1), 3-49.
Shepardson, D. P., Niyogi, D., Roychoudhury, A., & Hirsch, A. (2012). Conceptualizing
climate change in the context of a climate system: Implications for climate and
environmental education. Environmental Education Research, 18(3), 323-352.
Sternang, L., & Lundholm, C. (2011). Climate change and morality: Students' perspectives
on the individual and society. International Journal of Science Education, 33(8),
1131-1148.
Sternberg, R. J., & Davidson, J. E. (Eds.). (1986). Conceptions of giftedness. New York:
Cambridge University Press.
Sternberg, R. J., & Davidson, J. E. (Eds.). (2005). Concepts of giftedness (2nd ed.). New
York: Cambridge University Press.
51
Stuckey, M., Hofstein, A., Mamlok-Naaman, R., & Eilks, I. (2013). The meaning of
‘relevance’ in science education and its implications for the science curriculum.
Studies in Science Education, 49(1), 1-34.
Subotnik, R. F., Olszewski-Kubilius, P., & Worrell, F. C. (2011). Rethinking giftedness
and gifted education: A proposed direction forward based on psychological science.
Psychological Science in the Public Interest, 12(1), 3-54.
Tannenbaum, A. J. (Ed.). (1983). Gifted children: Psychological and educational
perspectives. New York: MacMillan.
Teaching Excellence in Adult Literacy (TEAL). (2011). Just write! -guide. Washington
D.C: US Department of Education, Office of Vocational and Adult Education.
Tirri, K. (2011). Holistic school pedagogy and values: Finnish teachers' and students'
perspectives. International Journal of Educational Research, 50, 159-165.
Tirri, K. (2012). What kind of learning environment supports learning of gifted students in
science? In A. Ziegler, C. Fischer, H. Stoeger & M. Reutlinger (Eds.), Gifted
education as a life-long challenge: Essays in honour of franz J. mönks (pp. 13-24).
Lit Verlag: Muenster.
Tirri, K., & Kuusisto, E. (2013). How Finland serves talented and gifted pupils. Journal
for the Education of the Gifted, 36(1), 84-96.
Tirri, K., Kuusisto, E., & Aksela, M. (2013). What kind of learning is meaningful and
interactive to gifted science students? A case study from millennium youth camp. In
K. Tirri, E. Hanhimäki & E. Kuusisto (Eds.), Interaction in educational domains
Rotterdam: Sense Publishers.
UNESCO. (1/2015). Education for sustainable development. Retrieved from
http://www.unesco.org/new/en/education/themes/leading-the-international-
agenda/education-for-sustainable-development/ on 1/2015.
UNESCO. (11/2014). World conference on education for sustainable development calls
for renewed commitment by all countries. Retrieved from
http://www.unesco.org/new/en/education/themes/leading-the-international-
agenda/education-for-sustainable-development/dynamic-content-single-
view/news/world_conference_on_education_for_sustainable_development_calls_for_
renewed_commitment_by_all_countries/#.VNiYUWOLfZY on 1/2015.
United Nations Conference on Environment and Development. (1992). Agenda 21:
Programme of action for sustainable development. New York: United Nations.
Westheimer, J., & Kahne, J. (2004). What kind of citizen? The politics of educating for
democracy. American Educational Research Journal, 41(2), 237-269.
52
Wood, J. (2015). A relational assessment system. Retrieved from
http://metadesigners.org/Iceland-New-Assessment-System on 2/2015.
World Commission on Environment and Development. (1987). Our common future.
Oxford: Oxford University Press.
Yager, R. E., & Hofstein, A. (1986). Features of a quality curriculum for school science.
J.Curriculum Studies, 18(2), 133-146.
York, R., Rosa, E., & Dietz, T. (2002). Bridging environmental science with
environmental policy: Plasticity of population, affluence, and technology. Social
Science Quarterly, 83, 18-34.
Zeidler, D. L., & Keefer, M. (2003). The role of moral reasoning and the status of
socioscientific issues in sicence education: Philosophical, psychological and
pedagogial consideration. In D. L. Zeidler (Ed.), The role of moral reasoning on
socioscientific issues and discourse in science education (pp. 7-38). Dordrecht,
Netherlands: Kluwer Academic Press.
... Science education can be re-conceptualized as an instrument of civic engagement through activities addressing societal, local, or environmental problems (Vesterinen et al, 2014), as well as activities examining more general socio-scientific issues (Pedretti & Nazir, 2011), to social justice initiatives, especially if students have agency in deciding the goals and procedures of their projects (Eilks & Hofstein, 2014;Sadler, 2011). Science education that is relevant to the individual student, as well as to society, can highlight the relationship between society and science, and bring issues crucial for citizenship education to the forefront (Falk, 2001;Sadler, 2011;Tolppanen, 2015), including systemic issues such as climate change, the impacts of settler colonialism, and economic inequality. Recent studies have found that youth are interested in participation and political engagement, particularly in actions that emphasize self-expression and self-actualization (Kahne & Westheimer, 2006;Quintelier, 2007). ...
... Other studies have failed to measure involvement in community development projects (Boyes et al, 2009;Sternäng & Lundholm, 2011;Zsóka et al, 2013), were based on quantitative analysis only (Zsóka et al., 2013), or focused primarily on students' reasoning and perspectives on a specific issue (Sternäng & Lundholm, 2011). Science educators also find incorporating societal issues into science education to be difficult (Tolppanen, 2015). Research conducted in schools indicates that even though teachers are mindful of a need for activities that address local and global problems and decisionmaking processes, they sometimes worry about their lack of competence to implement such approaches (Kahne et al, 2013;Pedretti et al, 2008). ...
... The process of participating in our project activated teacher candidates' understanding of the relevance and importance of citizen science education. As Tolppanen (2015) noted, science education that is relevant to students' lives and society, can bridge the relationship between science and society, and bring issues critical for citizenship education to the forefront. ...
Article
Citizen science, research in which members of the public actively contribute scientific data, has recently evolved as a means to support scientific inquiry in the classroom, particularly in fields related to ecology and environmental science. Our research focuses on a collaborative project with teacher candidates, a science education professor, and a social studies education professor at a Canadian university. Teacher candidates were engaged in the classroom and beyond as they explored topics related to civics education and evidence-based decision making. Our findings demonstrate the potential effectiveness of a citizen science lens for science, social studies, and generalist teachers. Key Words: citizen science, citizenship/civics education, science education, social studies education, teacher education La science citoyenne, c'est-à-dire la recherche dans laquelle les membres du public contribuent activement aux données scientifiques, a récemment évolué comme un moyen de soutenir la recherche scientifique en classe, en particulier dans les domaines liés à l'écologie et aux sciences de l'environnement. Notre recherche porte sur un projet de collaboration avec de futurs enseignants, un professeur d'enseignement des sciences et un professeur d'enseignement des sciences sociales dans une université canadienne. Les candidats à l'enseignement se sont engagés dans la salle de classe et au-delà en explorant des sujets liés à l'éducation civique et à la prise de décision fondée sur des preuves. Nos résultats démontrent l'efficacité potentielle d'une optique de science citoyenne pour les professeurs de sciences, d'études sociales et les enseignants généralistes. Mots clés : science citoyenne; éducation à la citoyenneté/civique; enseignement des sciences; enseignement des études sociales; formation des enseignants
... Science education can be re-conceptualized as an instrument of civic engagement through activities addressing societal, local, or environmental problems (Vesterinen et al, 2014), as well as activities examining more general socio-scientific issues (Pedretti & Nazir, 2011), to social justice initiatives, especially if students have agency in deciding the goals and procedures of their projects (Eilks & Hofstein, 2014;Sadler, 2011). Science education that is relevant to the individual student, as well as to society, can highlight the relationship between society and science, and bring issues crucial for citizenship education to the forefront (Falk, 2001;Sadler, 2011;Tolppanen, 2015), including systemic issues such as climate change, the impacts of settler colonialism, and economic inequality. Recent studies have found that youth are interested in participation and political engagement, particularly in actions that emphasize self-expression and self-actualization (Kahne & Westheimer, 2006;Quintelier, 2007). ...
... Other studies have failed to measure involvement in community development projects (Boyes et al, 2009;Sternäng & Lundholm, 2011;Zsóka et al, 2013), were based on quantitative analysis only (Zsóka et al., 2013), or focused primarily on students' reasoning and perspectives on a specific issue (Sternäng & Lundholm, 2011). Science educators also find incorporating societal issues into science education to be difficult (Tolppanen, 2015). Research conducted in schools indicates that even though teachers are mindful of a need for activities that address local and global problems and decisionmaking processes, they sometimes worry about their lack of competence to implement such approaches (Kahne et al, 2013;Pedretti et al, 2008). ...
... The process of participating in our project activated teacher candidates' understanding of the relevance and importance of citizen science education. As Tolppanen (2015) noted, science education that is relevant to students' lives and society, can bridge the relationship between science and society, and bring issues critical for citizenship education to the forefront. ...
Article
Full-text available
Citizen science, research in which members of the public actively contribute scientific data, has recently evolved as a means to support scientific inquiry in the classroom, particularly in fields related to ecology and environmental science. Our research focuses on a collaborative project with teacher candidates, a science education professor, and a social studies education professor at a Canadian university. Teacher candidates were engaged in the classroom and beyond as they explored topics related to civics education and evidence-based decision making. Our findings demonstrate the potential effectiveness of a citizen science lens for science, social studies, and generalist teachers. La science citoyenne, c'est-à-dire la recherche dans laquelle les membres du public contribuent activement aux données scientifiques, a récemment évolué comme un moyen de soutenir la recherche scientifique en classe, en particulier dans les domaines liés à l'écologie et aux sciences de l'environnement. Notre recherche porte sur un projet de collaboration avec de futurs enseignants, un professeur d'enseignement des sciences et un professeur d'enseignement des sciences sociales dans une université canadienne. Les candidats à l'enseignement se sont engagés dans la salle de classe et au-delà en explorant des sujets liés à l'éducation civique et à la prise de décision fondée sur des preuves. Nos résultats démontrent l'efficacité potentielle d'une optique de science citoyenne pour les professeurs de sciences, d'études sociales et les enseignants généralistes.
... Ympäristökasvatuksen ja kestävyyskasvatuksen tavoitteista ja erityispiirteistä on laadittu erilaisia malleja (mm. Hungerford & Volk 1990;Jeronen & Kaikkonen 2001;Käpylä 1991;Palmer 1998;Paloniemi & Koskinen 2005;Tolppanen 2015). Näissä malleissa korostetaan tietojen ja taitojen tärkeyttä, ja lähes poikkeuksetta niissä nostetaan esiin myös toiminnan, kokemusten ja asennekasvatuksen merkitys. ...
... Tästä syystä on tärkeää i) tunnistaa keskeiset kohteet, ii) arvioida, mitä muutokseen vaaditaan, iii) pohtia, miten yleiseen ilmapiiriin voidaan vaikuttaa ja iv) kannustaa ihmisiä toimimaan muutoksen edistämiseksi. Myös nykyistä ympäristövastuullista toimintaa tulisi reflektoida ja miettiä, miten sitä voidaan tehostaa (Tolppanen 2015). ...
... Malli voi auttaa kasvattajia pitämään eri ulottuvuudet paremmin mielessä, vaikka he keskittyisivätkin omassa opetuksessaan enemmän johonkin tiettyyn pyörän osaan. Kaikilla opettajilla tulisi kuitenkin olla käsitys ilmastokasvatuksen perusperiaatteista, esimerkiksi siitä, miten pirullisia ongelmia ja niiden herättämiä tunteita tulisi käsitellä opetuksessa sekä siitä, miten tiedon ja tekojen välistä kuilua voisi kaventaa (Tolppanen 2015). Lehtonen ja Cantell (2015) peräänkuuluttavatkin ilmasto-ja kestävyyskasvatuksen välttämättömyyttä kaikkien opetusasteiden opettajankoulutuksessa. ...
Article
Full-text available
Ilmastonmuutos on yksi tämän päivän suurimmista ympäristöhaasteista, mutta toistaiseksi ilmastokasvatusta toteutetaan varsin rajallisesti ja kapea-alaisesti. Tutkimustiedon ja kasvatuksen kuilun pienentämiseksi tässä artikkelissa esitellään kokonaisvaltaisen ilmastokasvatuksen malli, joka ilmentää ilmastokasvatuksen monialaista luonnetta ja erityiskysymyksiä. Malli perustuu tutkimukseen, ja ilmastokasvatuksen haasteita ja erityiskysymyksiä tarkastellaan transformatiivisen oppimisteorian valossa. Polkupyörämallin avulla esitellään ilmastokasvatuksen tärkeät osa-alueet, jotka ovat (i) tiedon lisääminen ja jäsentäminen, (ii) ajattelun taitojen kehittäminen, (iii) identiteetin, arvojen ja maailmankuvan huomioiminen, (iv) motivaation ja osallisuuden lisääminen, (v) toimintaan kannustaminen, (vi) tulevaisuuteen ohjaaminen, (vii) toiminnan esteiden tiedostaminen sekä (viii) toivon ja muiden tunteiden herättäminen. Artikkelissa myös esitetään, miten kokonaisvaltaista ilmastokasvatusta voidaan lisätä kouluopetuksessa. Asiasanat: ilmastokasvatus, polkupyörämalli, transformatiivinen oppiminen, ympäristökasvatus, kestävyyskasvatus
... One practical approach to generating interest in socio-scientific topics is to establish a connection between the topic and sustainable development. This is because scientific and social components are intricately intertwined with economic, social, and environmental dimensions (Tolppanen, 2015). As a result of the direct association between socio-scientific challenges and knowledge of Education for Sustainable Development (ESD), curriculum content must incorporate education for sustainable development (Kanapathy, et al., 2019;Osborne & Dillon, 2008). ...
Article
Full-text available
Keywords Abstract History learning video, socio-scientific issues, education for sustainable development, hydrocarbons and petroleum This open access article is distributed under a (CC-BY SA 4.0 License) Phone*: +6283145120470 This study aimed to develop learning videos based on socio-scientific issues in order to support education for sustainable development of hydrocarbons and petroleum materials for class XI Senior High School students. The method of the study was sequential exploratory mixed methods through the qualitative data collection stage, data analysis, and questionnaires. The developed videos contained three issues from the primary material in hydrocarbons and petroleum relevant to daily life. The created instructional videos are accessible online through the YouTube platform or via USB/Bluetooth file transfer. Usability and readability tests were performed to determine the feasibility of the generated learning videos; while the resulting percentages for usability and readability. Based on the result, videos were declared feasible by chemistry teachers and students at grade XI Senior High School so that videos can be used as the source of information based on the socio-scientific issue in order to support education for sustainable development of hydrocarbons and petroleum materials with usability and readability percentages respectively of 83.73% and 79.59%.
... As our society faces many challenging environmental, health and societal problems, developing action competence may be more relevant today than ever before. To help develop action competence and critical thinking skills, students need to be given the opportunity to examine, analyze and weigh different options (Tolppanen, 2015), for instance in their own consumption habits. ...
Chapter
This chapter examines how sustainability issues could be implemented into secondary school science using life cycle assessment (LCA) as a context. The chapter first presents a literature review on the previous studies where LCA has been used in secondary school education. The authors then use theory and practice to discuss how using LCA in science education has a lot of potential and how this potential is not fully realised. The authors argue that in order for LCA education to be relevant and holistic, it should incorporate different pedagogical approaches, such as (i) guided inquiry-based learning, (ii) participatory decision making (iii) and discussions and debates. Furthermore, in a secondary school context, LCA education should incorporate (iv) environmental, (vi) societal, (v) health and (vii) career-related issues, rather than focussing only on environmental issues. To conclude, the authors present a model that can be used to help implement guided inquiry into education when using LCA as a context to address sustainability issues.
... Tämä tarkoittaa keskustelua eettisistä kysymyksistä eri näkökulmista (Tirri, Tolppanen, Aksela & Kuusisto, 2012). Toimintaa ilmastonmuutoksen hillitsemiseksi tulisi tarkastella motivaation ja osallisuuden sekä toimintamahdollisuuksien näkökulmasta miettimällä, miten toimintaa voidaan tehostaa esimerkiksi lisäämällä tietoisuutta toiminnan esteistä (Tolppanen, 2015). Tulevaisuuden pohtiminen ja visioiminen sisältävät sellaistenkin päätösten tekemisen harjoittelua, joiden oikeellisuudesta ei ole täyttä varmuutta (Sterling, 2010). ...
Article
Full-text available
Tässä kvalitatiivisessa tutkimuksessa selvitettiin biologian ja maantieteen opetuksessa käytettyjä ilmastonmuutosta koskevia opetusmenetelmiä ja niiden tukemista tiedon ja ajattelun tasoista. Tutkimuskysymyksiksi muodostuivat: 1) Mitä ilmastonmuutoksen oppimista edistäviä opetusmenetelmiä biologiassa ja maantieteessä käytetään? 2) Millaisia oppilaiden tiedon ja ajattelun tasoja ilmastonmuutoksen opetuksessa käytetyt opetusmenetelmät tukevat? Tutkimukseen valikoitui 14 kansainvälistä tieteellistä artikkelia (N = 159). Valinnan kriteereinä olivat: oppisisältö, julkaisuvuodet 2000-2019 sekä kohderyhminä peruskoululaiset ja lukiolaiset. Lisäksi artikkelissa tuli olla ainakin yksi opetusmenetelmä. Opetusmenetelmät tutkittiin aineistolähtöisellä sisällönanalyysillä. Opetusmenetelmien tukemia tiedon ja ajattelun tasoja analysoitiin teoriaohjaavalla sisällönanalyysillä. Sekä biologiassa että maantieteessä yleisimpiä opetusmenetelmiä olivat tutkiva oppiminen, ongelmanratkaisu, ryhmätyöt ja opettajakeskeiset opetusmenetelmät. Maantieteessä käytettiin biologiaa monipuolisemmin erilaisia ilmastonmuutoksen opiskelua edistäviä opetusmenetelmiä. Opetusmenetelmät tukivat korkeampia tiedon ja ajattelun tasoja harvemmin kuin alempia. Osa käytetyistä opetusmenetelmistä mahdollistaa omien kokemusten jakamisen ja päättelyn ryhmässä, mikä tukee opiskelijoiden oman ajattelun ymmärtämistä ja kriittistä ajattelua.
... Furthermore, pre-service teachers should be made aware of their possible single-action bias (see Weber, 2010) by debunking their perceptions regarding the impact of different mitigative actions. One way to approach this would be to encourage the teachers to analyze their environmental actions critically (see Tolppanen, 2015), taking the carbon footprint of their actions into consideration. This process of critical analysis is what distinguishes environmental action from mere environmental behavior (see Jensen & Schnack, 1997) and at best can lead to a dissatisfaction of current understanding and the openness to accommodate new beliefs (Posner et al., 1982) and ultimately new behavior (Bandura, 2011). ...
Article
Full-text available
A 44-item questionnaire was created to examine pre-service teachers’ knowledge and perceptions of the impact of mitigative climate change actions and how willing they are to undertake these actions. Responses (N = 224) were collected from pre-service teachers at the University of Eastern Finland. The findings show that pre-service teachers have a very low level of knowledge of the impact of different mitigative climate change actions. Furthermore, the students tend to overestimate the carbon footprint of low-impact actions and underestimate the carbon footprint of high-impact actions and they are unable to make a clear distinction between low- and high-impact actions, though the impact of the high-impact actions may be many times greater than those of low-impact actions. In general, pre-service teachers were willing to take low-impact actions, somewhat willing to take mid-impact actions, but reluctant to take the highest-impact actions. Knowledge of the impact of actions did not correlate with willingness to act, possibly due to low levels of knowledge. Some correlation between confidence in knowledge and willingness to act was found. This article discusses the importance of considering confidence in knowledge in future research examining the relationship between knowledge and action. The implications of the findings on teacher education and environmental education are also discussed.
... The promotion of education on sustainable development is a central focus area in science education in chemistry. Research is conducted on the topic and theses are written, for example doctoral theses (Juntunen, 2015;Tolppanen, 2015). New virtual operating models for sustainable development and its promotion for both youth and teachers, have been researched and developed in a virtual science ________ 18 blogs.helsinki.fi/action-for-sustainability ...
Book
Full-text available
The science lab ChemistryLab Gadolin has been named after an internationally fa-mous Finnish Professor in Chemistry, Johan Gadolin (1760-1852), the father of Finnish chemical research. He emphasized the fact that inquiry has a central sig-nificance in the teaching of chemistry, which is why it also forms the basis for the operations of Gadolin. Johan Gadolin was one of pioneers of the promotion of in-quiry also internationally. Professor Gadolin had a strong effect on the Finnish In-dustry as a member of the Finnish Economic Society. Close collaboration with the Industry as well as developing new, inspiring solutions and pedagogical innova-tions together into science education in chemistry from early childhood education to universities, is also an important aim in the operations of Gadolin.
Article
This article presents and evaluates a model made for climate change education – the bicycle model. The model was created based on an extensive literature review, from which, essential aspects of climate change education were drawn out. The bicycle model is a representation of holistic climate change education and emphasizes the importance of the following aspects: knowledge, thinking skills, values, identity, worldview, action, motivation, participation, future orientation, hope and other emotions, and operational barriers. In this study, the model is also evaluated by climate education researchers and educators. The evaluation was done through documented group discussions and an electronic questionnaire. The findings suggest that the model is useful in developing climate change education policy, research and practice. The findings also give insight into expert's perceptions on climate education. Finally, the article discusses how this model could be developed further.
Book
This book: offers practical guidance in devising learning goals and suitable learning and assessment strategies; helps teachers to provide students with the skills and understanding needed to address these multi-faceted issues; explores the nature and place of socio-scientific issues in the curriculum and the support necessary for effective teaching; Science Education for Citizenship supports science teachers, citizenship teachers and other educators as they help students to develop the skills and understanding to deal with complex everyday issues.
Chapter
The aim of this chapter is to discuss what kind of learning would be interactive as well as meaningful in teaching gifted science students. Students are identified as being gifted based on their earlier school achievements and projects (see Table 1). The research reported here is a multiple-case study of five international students who attended the Millennium Youth Camp (MY Camp) in Finland in the summer of 2012.
Article
Climate change is one of the most serious global environmental problems and for that reason there has been lately a great interest in educating pupils, the future citizens, about it. Previous research has shown that pupils of all ages and teachers hold many misconceptions and misunderstandings concerning this issue. This paper reports on research concerning student teachers' perceptions about aspects of climate change as well as about greenhouse effect and ozone layer depletion. The aim of this research is to take findings into account for teaching student teachers about these issues. An open-ended questionnaire was used in order to gain a more comprehensive understanding of their thought. From their answers it appeared that these students believe that climate change is under way and base their beliefs on their own experience. They are unaware of the proper actions to be taken for slowing down the climate change, they also hold the misconception that ozone depletion, acid rain, and pollution in general are conducive to climate change. They confuse greenhouse effect with ozone depletion as far as the mechanisms through which they occur is concerned and the causal compounds. By taking into account these research findings the possible implications for teaching are discussed and some suggestions for more effective teaching are made.
Book
What does it really mean to be gifted and how can schools or other institutions identify, teach, and evaluate the performance of gifted children? The second edition of Conceptions of Giftedness describes the major conceptions of what it means to be gifted, and how these conceptions apply to identification, instruction, and assessment of the gifted. It will provide specialists with a critical evaluation of various theories of giftedness, give practical advice to teachers and administrators on how to put theories of gifted education into practice, and to enable the major researchers in the field to compare and contrast the strengths of their theoretical models.
Chapter
I was sitting in a conference room at the President Hotel in Gaborone, Botswana at a circle of conference tables with about 40 environmental education representatives of 12 Southern African countries. We were in day two of a workshop to critique a report proposing environmental education policy guidelines to the countries belonging to the Southern African Development Community (SADC). We had been moving nicely through the agenda when someone suggested that we replace “Environmental Education” in the title and throughout the report with “Education for Sustainability.”
Article
Teachers and meteorologists are among the most respected purveyors of scientific information to the public. As such, they can play an influential role in educating the public about basic atmosphere-related phenomena. To better fulfill this educational role, it is necessary to (i) identify and (ii) correct people's major misconceptions about climatic and atmospheric issues, including global climate change. This paper reports the results of a survey of high school students' knowledge and attitudes about climate change. The authors use open-ended survey questions to gain a more comprehensive understanding of the range of "mistakes" that are made. The results show misconceptions including inflated estimates of temperature change, confusion between ozone depletion and global warming, the perception of warmer weather and a belief that all environmentally harmful acts cause climate change. Also discussed is the origin of these mistakes from the perspective of current social scientific literature. It is suggested that these misconceptions arise from low levels of information, reliance on the televised news media, use of judgmental heuristics, confusion between weather and climate, and "fuzzy enviromnentalism," wherein students perceive disparate environmental harms as significantly interrelated. The study also reveals that students have a very high level of trust in scientists and teachers. This suggests a role for scientists and educators through which they help correct misconceptions about climate change and ensure that people adopt effective environmentally protective measures.
Article
Since the first use of 'scientific literacy' in the late 1950s, numerous science educators and policy makers have reconceptualised the term to such an extent that it has been described as being 'ill-defined and diffuse'. Despite this lack of clarity, the term is the focus of curriculum standards in many countries and is at the heart of international comparisons of student attainment including the Organisation for Economic Cooperation and Development's (OECD) Programme for International Student Assessment (PISA) study. Uncritical use of the term masks the existence of deep-seated philosophical clashes that hinder reform of science education in many countries throughout the world.