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Abstract

https://ora.ox.ac.uk/objects/uuid:8e175e19-f879-4827-9cbd-c4849cb6bd60
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Creating a Responsible Quantum Future
Creating a
Responsible
Quantum Future
The case for a dedicated national resource
for responsible quantum computing
18 November 2021
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Creating a Responsible Quantum Future
Contents
Executive summary 4
Background 4
“Questions of Responsibility” –
Impact Acceleration Award Research Project 5
Recommendations 5
Background 7
Quantum computers 7
Societal effects 8
Governance approaches 9
‘Hard’ governance 9
‘Soft’ governance 10
Responsible Innovation 11
Responsible Innovation in NQIT 12
Responsible Innovation Hub research project 14
Limitations 15
Research ndings 16
A need for responsible innovation 16
In academia 16
In industry 17
In policymaking 18
Consideration of societal impacts 19
Increase in ‘national’ approaches 19
The impact of public investment 21
Discussion and implications 23
Responsible Innovation resourcing 23
Consistent, focused Responsible Innovation 24
Potential impacts of investment shortage 24
Governance 25
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Creating a Responsible Quantum Future
Responsible Innovation Hub for quantum computingtechnologies 28
A roadmap for an RI Hub in quantum 29
Investment 30
Horizon planning, not scanning 30
Stakeholder input 31
International viewpoint 31
Conclusions 32
References 33
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Creating a Responsible Quantum Future
Executive summary
Background
Quantum computing may be closer now than previously predicted – thepace
of research is accelerating and timescales around when useful outputs
and workable quantum computing systems might be available seem to
haveshortened.
As with many novel technologies, quantum computing is highly likely to engender
societal changes, and previous experience with large-scale technologies and
innovations such as Nuclear, Genetically Modied Organisms (GMOs) and
Machine Learning, demonstrates that such changes are not always benecial,
or that benets are not shared equitably in society. Negative consequences of
such innovations can undermine trust, negate potential
benets, and may cause actual harms. Research shows1
that societal attitudes towards quantum computing and
quantum technologies are currently reasonably positive –
and in order to maintain (and be worthy of) societal trust
and acceptance, good governance is essential. TheUK
National Quantum Technologies Programme (NQTP) Statement of Strategic
Intent2 rightly says that “quantum computing could impact on society [in ways
that] are so profound it is hard to ignore”, and the National Quantum Computing
Centre (NQCC)3 repeatedly highlights the need for the UK to deliver societal
benets, prosperity, and security.
Governance can be responsive (typically legislation or regulation after harm
has been caused or a need is perceived) or pre-emptive (utilising anticipatory
techniques, and aspects of responsibility such as care and responsiveness).
1. EPSRC. (2017). Quantum Technologies Public Dialogue Report.
2. https://uknqt.ukri.org/les/strategicintent2020/
3. https://www.nqcc.ac.uk/wp-content/uploads/2020/09/NQCC-Strategic-Intent-v1.0.pdf
Quantum computing is
highly likely to engender
societal changes
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Creating a Responsible Quantum Future
Pre-emptive governance work in the form of Responsible Innovation (RI – also
known as Responsible Research and Innovation, or RRI) was included in the
Networked Quantum Information Technologies (NQIT) Hub at its inception;
but was not carried forward systematically in the Quantum Computing and
Simulation Hub that succeeded it. A follow up project to the NQIT-RRI4 work
was designed by the same team of RI investigators that had worked on NQIT to
ascertain whether there was a perceived need for ongoing RI work in the eld.
“Questions of Responsibility” – Impact Acceleration
Award Research Project
Our project “Towards a Hub in Responsible Innovation for Quantum Computing”
was funded by an Impact Acceleration Award from the University of Oxford.
Theresearch, consisting mainly of one-to-one interviews with key informants,
took place between April 2020 and May 2021. The work plan was considerably
altered because of the COVID-19 emergency.
The conclusion from the ndings of our investigations in this project is that such
a need is indeed perceived – indeed actively desired – by many of those working
on the development of quantum computing. After qualitative research work in
policy, academia, and industry loci for quantum computing over the last several
months, we have a snapshot of the quantum computing landscape. This has led
us to make several recommendations.
Recommendations
We perceive the need for:
1. A Responsible Innovation hub for quantum computing. The infrastructure
of the quantum computing programme in the UK has altered with the
creation of the National Quantum Computing Centre, but the need for a
responsible innovation outlook has only increased with the relatively closer
prospect of commercialisable quantum computing. The NQCC would be a
key player with involvement in pre-emptive governance activities.
2. Central government investment. Government participation, through the
National Quantum Technologies Programme and in other ways, can create
capacity, demonstrate condence, maintain a public-sector interest in the
4. For that project we used the alternative term Responsible Research and Innovation (RRI)
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Creating a Responsible Quantum Future
technology, and provide ongoing governance with the appropriate level of
granularity.
3. Horizon planning. Development of the sector is moving at pace and it is
vital to guide its development in order to try and ensure benecial societal
impacts and public trust.
4. Stakeholder input. There are numerous bodies and institutions that will
be affected by quantum computing technologies and there is an urgent
need to bring them up to speed and involve them in discussions around
development.
5. An International viewpoint. Quantum computing is
a nation-state level technology with a high degree of
competitiveness internationally. The need to balance
benets to society as a whole while mitigating risks of
potential misuse and protecting the UK’s investment
is a core theme of responsible and trusted research
and innovation. The UK should take an active part in
the CEN-CENELEC Focus Group and ETSI standards
groups on quantum technologies.
We conclude that the UK requires a roadmap for the responsible development
of quantum computing technologies, and we here suggest such a roadmap for
discussion and development.
Carolyn Ten Holter
Marina Jirotka
Philip Inglesant
Oxford 2021
Quantum computing
is a nation-state
level technology
with a high degree
of competitiveness
internationally
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Creating a Responsible Quantum Future
Background
Quantum computers
The last two decades have seen rapid and accelerating developments in the
quantum computing eld. A quantum computer uses ‘quantum bits’ (qubits)
to perform its operations, harnessing quantum mechanical phenomena of
superposition and entanglement to outperform a classical computer in particular
types of calculation such as, large-number factoring and optimisation of
multiple variables (Lu, 2019). Quantum physics
also enables features which are not possible
classically: these include true randomisation
(Aaronson, 2014) and simulation of processes
at the quantum level (Feynman, 1982). The
advantages that may attach to such performance
are generating enormous amounts of interest
from the world’s largest technology companies
as well as many research-focused organisations,
and signicant sums are being invested into
building quantum computers (Gibney, 2019).
Gibney (2019) also points out that the sector is
increasingly populated by start-ups in Quantum Computing Technologies (QCT)-
adjacent technological development, (forexample specialised start-ups in elds
such as “deep physics”, in ways to implement qubits, in quantum algorithms,
and in quantum communications), which demonstrates a move beyond the
research phases of this work and into commercialisation. Globally, the quantum
computing market was estimated to be worth £389m in 2019, with predicted
growth to £50bn by 2030 (ResearchAndMarkets.com, 2020).
Novel technologies such as QCTs can affect society in both positive and
negative ways, as has been seen with various other technologies such as
Machine Learning. Machine Learning can provide signicant advantages in elds
A quantum computer uses
‘quantum bits’ (qubits) to
perform its operations,
harnessing quantum
mechanical phenomena
of superposition and
entanglement to outperform
a classical computer in
particular types of calculation
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Creating a Responsible Quantum Future
that handle large quantities of data and have a focus on pattern-recognition.
This facility has enabled major advances in, for example, skin-cancer care –
thetrained Machine Learning model has proven to be adept at helping to identify
cancerous lesions (Hekler et al., 2019). However, this same Machine Learning
technology, when used for facial recognition applications, has been shown both
to entrench and amplify existing biases in both data and practice against people
of colour (Garvie, 2019). Negative impacts such as these on society can and
do cause societal pushback and loss of trust – in the case of facial recognition,
forexample, there are growing campaigns to outlaw its use. IBM, among others,
has recently announced a halt to its facial recognition work (Krishna, 2020), and
several cities around the world have prevented local law enforcement agencies
from using the technology. This gives rise to the possibility that the positive
uses of Machine Learning may become ‘tainted’ by those that are perceived to
have negative effects. The example of Machine Learning shows that the ways
in which new technologies are driven, shaped, introduced, and regulated can be
critical both for societal acceptance and to ensure that society can receive the
benets while limiting possible negativeeffects.
Societal effects
The affordances of quantum computing may also have signicant effects on
society. Predictions of these affordances are varied – for example QCTs may
allow for high-speed optimisation of large numbers of variables, or simulation
of quantum processes, making them valuable for new drug discovery and many
other elds. On the negative side of these possible affordances, it is widely agreed
that quantum computing of sufcient capacity is
likely to have the ability to break existing cybersecurity
protocols through rapid large-number factoring
(Vermeer & Peet, 2020). Clearly, the importance of
secure communications in an era of embedded and
growing Internet dependence is vital, so in order for the
positive aspects of quantum computing to be realised,
potential negative effects such as the impact on
cybersecurity must be minimised to try and ensure that society can and will trust
the technology. The threat to secure communications is already being addressed
by post-quantum cryptography (Bernstein, 2009), butas with Machine Learning
and internet technologies, it is not possible to predict with any certainty what the
societal impacts will be some years into the future.
In order for the positive
aspects of quantum
computing to be realised,
potential negative effects
must be minimised
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Creating a Responsible Quantum Future
Efforts have already been made to engage with publics on quantum computing
technologies – the Public Dialogue exercise carried out in 2017 represented a
signicant outreach operation that aimed to assess public understandings of
quantum and levels of condence in the technology (EPSRC, 2017). It found
that “support for the development of quantum technologies grew as people’s
understanding increased, provided that research was subject to proportionate
governance mechanisms.” The House of Commons Science & Technology
Committee too has addressed this, supporting the call for governance and the
need for public condence in the technology (House of Commons Science and
Technology Committee, 2019).
Governance approaches
Governance can broadly be divided into two types – retrospective (backward-
looking) and anticipatory (or forward-looking). Retrospective types – ‘hard’
governance – include regulation and legislation and are not usually instigated
until harms have already occurred. Prospective, forward-looking or ‘soft’ forms of
governance include Responsible Innovation and other approaches (such as Real-
Time Technology Assessment and Participatory Design) that seek to improve
societal outcomes and prevent harms from occurring.
‘Hard’ governance
It is possible and even likely that quantum computing technologies will, in the
future, require regulation. However, regulatory processes are less than ideal
for technological challenges that may be subtle, complex and fast moving.
Regulation is generally slow, is often difcult to accomplish, and is generally
reactive rather than pre-emptive – usually meaning that harm has already
occurred. In addition, waiting for a regulatory infrastructure can also leave
spaces for disruptive technologies to burgeon at high speed. This is readily
demonstrated by examples such as Airbnb, which took
advantage of lacunae in existing law and has now created
such signicant societal problems that cities across the
world are actively trying to limit its reach (Chee, 2020).
There is currently no UK legislation that specically
applies to quantum technologies – these technologies
are at such an early stage that it would not be a good
use of legislative time to enact laws or regulations that may never be needed
or may be inapplicable. In the case of quantum, therefore, ‘soft’ approaches to
governance may seem to be indicated.
In the case of quantum,
‘soft’ approaches to
governance may seem
to be indicated
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Creating a Responsible Quantum Future
‘Soft’ governance
If possible, it is better to address challenges before they arise than to wait
for harms to occur, particularly when such harms are likely to undermine
societal trust in the technology (as in the Machine Learning examples above).
‘Hard’governance tools such as regulation can be supplemented, rounded-out
and supported by ‘soft’ governance approaches that have the advantage not
only of trying to pre-empt problems, but of providing the agility and granularity
necessary to respond to rapidly developing situations. These approaches are
anticipatory, reective, inclusive, creative, and responsive (Stilgoe, Owen, &
Macnaghten, 2013), rather than backward-looking and restrictive.
There is some work being carried out on prospective governance within
quantum– for example, the IEEE is looking at preliminary informal standards
around performance benchmarks and terminology in quantum computing
(IEEE, 2019) and there are also quantum industry bodies such as the Quantum
Economic Development Consortium (QED-C) in the US
that seek to proactively create codes of conduct. These
approaches focus on the creation of high-level agreements
that can form a well-regulated market in the quantum
computing industrial sector. There are also some high-prole
calls for a ‘quantum ethics’ that can reect and advise on
some of these societal challenges (Khan, 2021), and a series of workshops on
societal risks by the World Economic Forum working towards a set of principles
for quantum computing governance.
However, these approaches, although essential as part of a comprehensive
governance framework, may be regarded as insufcient. They are focused either
on technical standards (such as the meaning of quantum ‘advantage’) and the
action of the marketplace, or high-level questions around concepts such as
justice and benecence. These are certainly necessary, but omit several key
factors that, we argue, also need to be considered. For example, standards-
based approaches do not take into account the societal impacts of these novel
technologies, nor do they address questions of innovators’ responsibilities.
It was concerns such as these – of societal impact and the responsibility of
innovators – that led to the incorporation of a Responsible Innovation strand
in the rst phase of the UK’s quantum computing Hub, Networked Quantum
There are also some
high-prole calls for
a ‘quantum ethics’
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Creating a Responsible Quantum Future
Information Technologies (NQIT). The quantum computing Hub was one of
four quantum Hubs – the others focused on quantum sensing; imaging; and
communications (EPSRC, 2020). The UK is not the only jurisdiction to consider
prospective governance to be key – there are calls in the US for a ‘soft law’
approach that retains agility while also protecting end-users (Johnson, 2019).
However, the Responsible Innovation work was not renewed in 2019 with the
same level of resources when the Quantum Computing and Simulation Hub
took forward the work of NQIT, despite recommendations to do so (House of
Commons Science and Technology Committee, 2019).
Responsible Innovation
There are many methods for trying to respond in an iterative, agile manner to the
challenges presented by emerging technologies. Responsible Innovation (RI) is
only one such approach. Although denitions of RI vary, perhaps the most useful
comes from the RRI Tools project:
“RRI is a way to do research that takes a long-term
perspective on the type of world in which we want
to live… [RRI means] involving society in science and
innovation‘very upstream’ in the processes of R&I to
align its outcomes with the values of society.
(www.rri-tools.eu)
This denition emphasises the long-term view, and societal impact, as well
as the necessity for reecting on the features we want our future to have. The
other signicant features are the need to instigate such soft governance at early
stages in developmental processes, and to involve the society within which the
technology will operate. These requirements are semi-formalised within the
Anticipate-Reect-Engage-Act (AREA) Framework that has been adopted by the
EPSRC in the UK (Stilgoe et al., 2013).
The RI methodology, drawing on this Framework, combines consultation
with those who may be affected; consideration of both negative and positive
outcomes; and potentially inuencing the course of a technology if deemed
necessary. RI has gained attention since the turn of the century, partially as
a response to some of the public failures around emerging science of the
last few decades, such as the BSE crisis and genetically modied organisms
(GMOs), and has become embedded within European and UK policy frameworks
Responsible Innovation
is a way to do research
that takes a long-term
perspective on the type
of world in which we
want to live
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Creating a Responsible Quantum Future
(deSaille,2015). RI aims to ensure that research and
innovation are carried out for and with society in order
both to increase acceptance and to improve outcomes
for society (Owen, Macnaghten, & Stilgoe, 2012). There
is work on Responsible Innovation in nanotechnology
(Pandza & Ellwood, 2013), in synthetic biology (Ribeiro
& Shapira, 2019) and in climate engineering (Stilgoe et al., 2013) – all complex,
large-scale novel technologies. This makes Responsible Innovation a useful
candidate for trying to anticipate and respond to the potential societal impacts
ofQCTs.
Responsible Innovation in NQIT
RI was a core work package in the Networked Quantum Information
Technologies (NQIT) Hub, one of the four research hubs funded as part of the UK
National Quantum Technologies Programme. The work aimed to:
· provide a background to RI within the computing hub;
· identify the challenges for RI in NQIT;
· make recommendations about how to handle these challenges;
· and nally describe a framework and pathway to implement a tailored RI
process in NQIT
(Inglesant, Hartswood, & Jirotka, 2016).
NQIT-RRI focused on qualitative techniques for its study. Quantum technologies
as a eld is highly specialised, very focused, and relatively small, meaning that
in general qualitative work was deemed to be more useful for the questions the
research sought to investigate. What the project examined in depth was not
just the state of the art in terms of technical progress, and how this might relate
to societal impacts, but also the positions of the researchers and engineers
themselves in relation to societal concerns and the technologies they were
progressing in their work.
The methods included interviews, case studies, focus groups, a workshop
focused on defence and national security issues in quantum, and ultimately a
series of roadshow workshops to demonstrate and disseminate the work of all
four Hubs. The research was not only investigating and tracking the Responsible
Innovation approaches within the Hub but simultaneously co-creating them in a
RI aims to ensure that
research and innovation
are carried out for and
with society
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Creating a Responsible Quantum Future
participatory, action research modality. It is important to note that the focus
of the NQIT-RRI team was not to be responsible for all the RI activity in the
Hub, but rather to act as sources of expertise, generators of discussion, and
facilitators of RI-focused conversations. The team produced reports and
policy briengs that aimed to engage with stakeholders and create a resource
that could be accessed by those assessing future work, including a survey
of the landscape of RRI in quantum computing (Inglesant et al., 2016) and a
report of the defence implications (Inglesant, Jirotka, & Hartswood, 2018).
The work of the NQIT Hub concluded in November 2019. Subsequently,
a further round of funding supported the creation of the UK Quantum
Computing and Simulation Hub (QCS) as part of the second phase of
the UK’s quantum effort, with funding ongoing until 2024. Funding via UK
Research and Innovation (UKRI) has also created a National Quantum
Computing Centre, which will act as a central hub for the UK’s quantum
computing community (UK NQTP, 2019).
However, the RI work that had been included in the NQIT project was not
funded in QCS in terms of providing expert support and personnel. The NQIT-
RRI project team therefore sought independent funding to assess whether
there was a need for the creation of a Responsible Innovation Hub. Such a
Hub would be in a position to provide specialist support and expertise to the
quantum technologies community.
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Creating a Responsible Quantum Future
Responsible Innovation Hub
research project
Given the acceleration of progress within quantum computing research and
technological development, and the absence of a dedicated responsible
innovation resource within the second round of the quantum computing
hub, this is now the time for assessing the need for an ongoing, specialist
RI approach within quantum computing technologies. It is clear from rapid
advances such as Google’s claim to have achieved quantum advantage (Murgia
& Waters, 2019), the emergence of specialist quantum computing development
companies, the availability of cloud-based access to early quantum computers
such as IBM Quantum5 and development environments, that the sector and the
technology are moving fast. These factors led the NQIT-RRI team to seek an
Oxford University Impact Acceleration Award in order to carry out a ‘snapshot’
ofongoing work on quantum computing.
The research was carried out from October 2020 to January 2021. 40 individuals
working in the quantum computing sector were approached for interview. These
individuals work across academia, in industry start-ups, and in policymaking
areas. Of these 40, 20 agreed to participate.
Table 1 shows the distribution of roles among the
participants: n>20 because some participants held
more than one position (eg a university position and
also a business role). Participants were asked to
elaborate on their views from both perspectives.
Interviews were semi-structured, following the same broad framework of
questions each time, but with scope to discuss questions in more depth
if participants were happy to expand on points, and to allow space for
5. https://quantum-computing.ibm.com/
Table 1
Industry 7
Policy 5
Academia 10
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Creating a Responsible Quantum Future
investigating potentially useful avenues. The average length of a discussion
was 35-40 minutes. Interviews were given a randomly allocated numerical
code. Transcriptions were redacted at the point of transfer from voice to text,
then loaded into NVivo qualitative analysis software6. Analysis was carried out
inductively, with themes emerging from the written transcripts of the interviews
through an open coding process (Braun & Clarke, 2006).
Limitations
1. The research study was relatively small and relatively brief. Further work
may be needed across a broader spectrum of quantum sector participants
to gain a wider perspective on these ndings – this could be done through
the use of a survey instrument.
2. It is possible that those who agreed to participate in the study were
already biased in favour of responsible innovation approaches – a broader
survey as suggested above could attract a wider variety of views.
6. https://www.qsrinternational.com/nvivo-qualitative-data-analysis-software/home
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Creating a Responsible Quantum Future
Research ndings
Several themes emerged from the interviews:
i. A need for Responsible Innovation
ii. Consideration of societal impacts
iii. Increase in ‘national’ approaches
iv. The impact of investment
The key points are summarised below, before we examine the implications and
offer recommendations for further research and practice.
A need for responsible innovation
In academia
Participants working in quantum elds of research were
quick to argue for the necessity of responsible innovation
approaches. Insights ranged from the perceived
necessity of engaging with stakeholders and publics, to
a requirement for anticipatory work that could examine
possible benets and downsides.
“what we are all doing on a day to day basis may have a very
signicant impact on society. And therefore, we must be conscious
of that, we must answer questions of society about any concerns or
worries or hopes that they may have for this technology. So … we have
an obligation to engage.I7
“for people that are on the brink of building a world changing
technology, you should think seriously about what you’re doing” I11
Participants working
in quantum elds
of research were
quick to argue for the
necessity of responsible
innovation approaches
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Creating a Responsible Quantum Future
“what I wanted… was to create a whole series of [reports] - and to
directly impact the public, to directly impact sectors, to directly impact
policy. And to have a much higher prole.I15
However, it was also clear that there was limited capacity for undertaking
work such as this. Although academics were certain their work was being
carried out in accordance with well-understood research integrity frameworks,
familiar from training and from peer-review processes, they also understood
that the requirements of Responsible Innovation go several steps beyond such
frameworks and operationalise a long-term perspective that links current work to
future consequences. Taking these steps was viewed as something beyond their
training, experience, and possibly beyond their remit, which is still seen as the
production of ‘good science’.
“I haven’t spent a lot of time thinking about whether it would be
desirable to have better machine learning classiers and whether it
would be desirable to live in a world where there’s an algorithm that’s
analysing your transaction data…" I11
In industry
As research moves beyond foundational science into ‘innovation’ or
developmental phases and adoption by industry, commercialisation imperatives
(making products that can be sold) render possible concerns about impact
more immediate. Again, the requirement for Responsible Innovation was clear
to participants, and the potential impact on industry should there be substantial
public pushback or science scandals.
“The big example for me … is how it all went with nuclear. And, you
know, nuclear was another … high prospects, physics-led innovation
… and whatever you might think about the merits … there’s a whole
difculty, because of the way the perception of the industry has
developed.I13
“I see responsible innovation as very important - as a thing for
everyone to think about.I10
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Creating a Responsible Quantum Future
“if you think about, if you deal in a responsible way it’s ingrained in
your… company culture.I17
But this need to embed RI into company culture is – particularly in smaller
start-ups and SMEs7 – potentially in tension with the requirements of large
venture-capital investors, who may be unwilling to support approaches that
they may view as constraining creativity, or that may
affect (for example) decisions around where to purchase
resources, or have work carried out. Smaller companies
may nd it extremely challenging to devote resource to RI
training, concerns or initiatives, particularly when they are
required to make a return on investment. The lack of either
incentives or compliance requirements for RI measures
makes it a low priority.
In policymaking
Interviews with policymakers demonstrated their understanding of ‘de
facto’ responsible innovation-type approaches within their own work. This
might be through such measures as i) using anticipatory approaches to
consider possible benets or harms; ii) engaging with stakeholders; and
iii) understanding the ability to affect trajectories by becoming involved at
‘upstream’ points. This applied even if they were not specically using terms
that included ‘responsibility’. Those involved in overseeing the creation of a
quantum sector were particularly aware of the potential impact of negative
outcomes on a burgeoning industry. RI is seen as a tool with which to
manage the risks associated with new technologies in terms of providing a
guardrailapproach.
“I described it as crucial because it is…. you can cripple an industry
before it even gets going. Because you don’t even, you don’t even
impact the dialogue in any meaningful way. You can say it’s safe, and
people won’t believe you.I15
“responsible innovation - you know, it is an important part of the
programme as a whole, not just for [quantum] computing. And at the
7. Small-to-medium sized enterprises are dened in the UK as companies with two out of three of:
fewer than 250 employees; turnover less than £25m; gross assets of less than £12.5m
Smaller companies
may nd it extremely
challenging to devote
resource to RI training,
concerns or initiatives
19
Creating a Responsible Quantum Future
moment, I don’t think it’s planned in to the programme
in terms of the forward look, but it’s something we
would like to be!” I19
“this is the stuff we need to be thinking more about” I20
This recognition of the need for anticipation, engagement
and early inuence on trajectories is valuable, but can only be of limited value if
all of the outreach comes from one side of the discussion.
Consideration of societal impacts
In some respects, the potential impacts on society are already being considered,
particularly those that affect security. The dual-use nature of quantum
computing has ensured that it is part of the purview of organisations such as the
MoD, NCSC and GCHQ to consider its possibilities. However, interviewees were
clear that these considerations are not necessarily being applied in wider societal
contexts.
“there is always, there needs to be this thought of society in terms of
impact” I17
“we’re talking about timelines on quantum computers and capabilities,
but you know, what else? What are we … missing here? When it comes
to societal impact, whether it’s economic or quality of life” I07
Interviewees were almost uniformly aware of a sense of urgency in terms
of considering the possible impacts of quantum computing technologies
on society, and also displayed a strong awareness that no organisation or
group is currently tasked with either undertaking or drawing together work on
societalimpact.
Increase in ‘national’ approaches
The nature of quantum computing research is such that it requires signicant
levels of support in terms of resource. Building a quantum computer is now also
being seen as a matter of national prestige, in addition to potential impacts on
cybersecurity, discussed above, if a quantum computer were available to a rival
nation or non-state actors.
This recognition of the
need for anticipation,
engagement and
early inuence on
trajectories is valuable
20
Creating a Responsible Quantum Future
“there was a tweet by…Ivanka Trump8 … going ‘yep, US declares
quantum supremacy’” I10
All these factors contribute to governments now
taking considerably greater interest in the progress
of quantum computing, and participants in the
study agreed that the research had become an
international ‘race’. They cited phrases such as
‘sovereign capability’ that were now being heard
more frequently in policy-related discourse.
“it’s becoming a bit geopolitical… China’s Premier … mentioned the need
for China to invest in quantum technology … Europe has a programme,
the UK has its own programme, and the US recently announced a
programme last year.I11
“we’ve seen this …in quantum key distribution… there’s a … big US-
China rivalry that’s …developed. And we’re also seeing it quantum
computing”I10
Many interviewees were pragmatic about whether the UK would be able to
compete in such a race in the longer term, given that much larger players with
much deeper pockets were now on the eld.
America wants one, and China wants one, and … you can only have a
certain number” I14
Optimism remained, however, about the UK’s standing in this international
race, given its genuinely world-leading progress in many quantum computing
technologies, but the most realistic model to aim for was seen as similar to
that in Singapore, Taiwan, Japan and other countries with highly focused and
relatively powerful technology sectors. The UK has the ability to position itself
as a key component in the global supply chain, which in the longer term may be
more valuable than being the rst to build a scalable quantum computer.
8. https://twitter.com/IvankaTrump/status/1186987509609385988
Phrases such as ‘sovereign
capability’ [are] now being
heard more frequently in
policy-related discourse
21
Creating a Responsible Quantum Future
The impact of public investment
Interviewees were divided about the levels of
investment in quantum and its effects. There was
concern in some quarters that large amounts of
funding in academia were encouraging people to
make their projects sound more “quantum-y” in
order to be able to respond to funding calls, and
some noted that large awards had generated
professional jealousies and tensions in a eld that until fairly recently had been
a relatively small and closely collaborative community. These outcomes may
be viewed as undesirable but need to be balanced by alternate concerns that
insufcient investment over a number of years has led to capacity challenges
that can already be seen in academia.
“lots of places want to fund this research but they’re not nding
the people to hire … because … governments were not funding the
PhDstudents and postdocs to work in this area.I10
“we’re already seeing this at senior level, where… many of the people…
have been snapped up by large companies and also by by start-
ups… We have several projects … that we’re really struggling to hire
peoplefor” I10
Towards the innovation and commercialisation end of the sector, the concern
was again that there was insufcient funding available to truly enable a ourishing
quantum sector, and that the capacity shortages being seen in academia may
well be carried forward to commercial sectors in the future as start-ups struggle
to expand. This is also tied up with concerns that lack of investment will make
it challenging to retain talent in the UK – foreign or private investment may
encourage teams to move to other regions – creating further capacity issues.
“he’s raised $400 million … and he’s taken the workforce out of the
UK.”I15
Capacity is also not the only issue caused by a lack of investment. A further
domino-effect concern was that this type of research – once it starts to be
increasingly carried out within private companies – becomes subject to many
There was concern in some
quarters that large amounts
of funding in academia
were encouraging people to
make their projects sound
more “quantum-y”
22
Creating a Responsible Quantum Future
more limitations imposed by the need to protect intellectual property and operate
in a highly competitive environment.
“there are probably increasingly numbers of programmes … in
various regions, where it’s not … visible what researchers are doing
anymore.”I07
Also expressed was the likelihood that – should private companies become the
primary investors in this potentially extremely high-value sector – the impact on
societies was likely to be less benecial than if control over quantum computing
capacity is widely and equitably shared, supported by public investment.
“if the result is that these companies end up being the ones that have
the only quantum computer in the world … then this is not necessarily
a good thing for humanity” I10
Another reason for government to be a major
investor in this sector is that quantum start-ups
may have a long gestation period before returns
can be made. Additionally, like any nascent
sector, there is likely to be a high percentage
of failures. Investment is needed for these
relatively high-risk, slow-burn start-ups from investors with deep pockets who are
willing to potentially wait a considerable time for a return on investment.
“an industry has to grow and then be self-sustaining and expanding,
but you’ve got to support it until then and you’ve got to give it
condence - so government, in my view, needs to be the rst
customer.I15
“enabling companies to get access to nance … is a key issue …
because there are concerns that the UK market just doesn’t have the
right sorts of funds to continue to invest.I19
Investment is needed for these
relatively high-risk, slow-burn
start-ups from investors with
deep pockets
23
Creating a Responsible Quantum Future
Discussion and implications
Responsible Innovation has been applied in a number of emerging and
fundamental areas of technology, including ICTs (in a project led by one of the
authors of this roadmap9) and in earlier stages of quantum computing in the
NQIT Hub (led again by this author and another author was the main researcher).
It might be argued that quantum computing is not sufciently different from
other technologies to require a separate RI effort. We argue, however, that
quantum computing has distinguishing features which are quite different from
classical computing and requires a distinct
approach. Participants in this research were clear
that quantum computing is a powerful technology,
of great potential signicance to the UK economy,
though in ways that are not yet clear, in use-cases
that are as yet unknown, and in a timeframe that
is also subject to signicant shifts. Additionally,
these rapidly developing innovations are set within
a continually shifting and highly competitive international context. In the face
of uncertainties like these, there would seem to be a clear and present need for
well-dened channels of communication among policy, research, and industry,
an ability to respond rapidly to new developments, a cohesive policy and
governance strategy, and a programme of outreach to stakeholders including
civil society.
Responsible Innovation resourcing
Many of the requirements detailed above are within the remit of high-level
public policy, and would be beyond the scope of this report to discuss in any
depth, but our interviewees clearly expressed the importance of responsible
innovation, broadly understood. Although participants demonstrated a range
9. Framework for RRI in ICT - https://www.cs.ox.ac.uk/projects/frriict/index.html
Quantum computing has
distinguishing features which
are quite different from
classical computing and
requires a distinct approach
24
Creating a Responsible Quantum Future
of understanding of responsible innovation principles, there was unanimity on
the importance of ‘responsible’ approaches and the need to be very clear with
those potentially affected – stakeholders including the general public – about
what may be coming over the horizon. What was equally clear was the dearth of
resource dedicated to carrying through such responsible innovation approaches.
Without such resources, these issues, while recognised as important, risk
being swept away in the tide of innovation.
Participants expressed disappointment in the lack of
resource when it came to responsible innovation expertise
for them to call on. One interviewee commented that they
would keep a dedicated responsible innovation person
“really busy”– responsible innovation approaches are
viewed by the majority as bringing a valuable perspective
that is seen as essential in helping support the quantum
sector as it nds its way to maturity.
Consistent, focused Responsible Innovation
In particular, this research identied a need to consider societal impacts. In some
very specialised respects this is being addressed, but where such consideration
is taking place, it is either very focused on one particular aspect – such as
post-quantum cryptography – or it is very piecemeal, as demonstrated by the
regulatory and policymaking participants who expressed frustration at the
disjointed approaches they perceive in these areas. It was clear that some of
the policymakers interviewed had carried out horizon-scanning, anticipatory
work and perceived a need to engage with the quantum sector – however, an RI
approach within the quantum computing eld would have demonstrated a need
to engage on their part. Such reaching-out to potentially-affected sectors on a
systematic basis should be a part of a well-rounded and thorough RI approach,
embedded throughout quantum computing elds – participants did not see this
happening in a programmatic way.
Potential impacts of investment shortage
Participants discussed the numerous problems that could arise from a lack
of nancial support, some of which only come to light as knock-on effects
fromothers.
Participants expressed
disappointment in the
lack of resource when
it came to responsible
innovation expertise
25
Creating a Responsible Quantum Future
One of the obvious impacts is that restricted funding creates capacity shortages
at PhD level. This then has implications not only for ongoing academic research
projects but also creates skills shortages in industry, and may lead to relocation
of key companies to other countries and/or the departure of skilled professionals
(‘brain drains’). Lack of the right type of investment may also mean that
grassroots areas of the sector are hindered in their ability to grow (forexample
the challenge of companies that spin out from universities no longer having
access to university hardware, which can be enormously expensive to replace),
leaving the UK trailing internationally and unable to compete for supply-
chainroles.
Other impacts are also likely from under-investment. In a sector where highly
competitive and well-funded private sector companies are either buying up
start-ups, investing in them, or taking in large numbers of postgraduates, a
privatisation of quantum computing would likely prevent government from
remaining closely engaged with developments across the sector. Additionally,
when private companies invest in research, that research may tend to be
guarded as intellectual property within those companies, rather than made
public. A large-scale private company takeover of the sector could create a
situation where public bodies are entirely dependent on the private sector for
their quantum computing supply requirements.
However, perhaps the most signicant effect of under-
investment would be the impact on governance, and the
potential implications for public trust.
Governance
As previously discussed, ‘soft’ governance approaches are
more exible than ‘hard’ approaches and do not need to wait
until harms have been caused. Responsible innovation is only one such pre-
emptive approach, but what all such approaches have in common is that they
aim to prevent harm by operating proactively rather than reactively. A lack of
government investment, discussed above, could result in state government
effectively being ‘shut out’ from the sector. This would render effective soft
governance extremely difcult. Given the need, and public demand, for
governance of novel technologies such as quantum, it would seem clear that
policymakers and governmental agencies need to remain well-informed and
Perhaps the most
signicant effect of
under-investment
would be the impact
on governance
26
Creating a Responsible Quantum Future
closely involved with the quantum sector. Government that retains involvement
in the sector through a variety of levers (many of them necessarily economic)
at different levels of granularity – such as funding for projects, capital support
for equipment, investment in startups, committee oversight, and other
mechanisms– is more likely to retain the inuence needed for ‘soft’ governance.
A lack of such governance levers may create a perception that this novel
technology is essentially ‘ungoverned’.
27
Creating a Responsible Quantum Future
Recommendations
It is clear from this research, carried out in all three strands of the triple-helix
model (academia, industry and policy), that quantum computing – although still a
nascent technology – has the potential to form a highly signicant and inuential
sector of the UK economy, in terms of both nance and impact. Notonly is
access to stable quantum computing capacity likely to have important effects
on other sectors (such as pharmaceuticals, nance, manufacturing, distribution),
but UK specialist quantum component companies have the opportunity to form
a valuable and specialised part of the worldwide quantum computing industry.
The effects of the growing optimism around quantum computing are already
being felt, as reports into the growth of the sector show, and it is evident to those
closely involved that the pace of development and change has increased. This
research has demonstrated some of the challenges faced by those in the eld
and the issues that they view as important.
The potential importance and impact of quantum computing therefore make it
crucial to retain and support a relationship of trust with society throughout the
process of sectoral growth and establishment, as well as to retain the ability to
guide and inuence that sectoral growth. Societal concerns have already been
discussed in the House of Commons Science and Technology Committee report
(House of Commons Science and Technology Committee, 2019), which reected
on the public’s requirement for governance in quantum
computing technologies. There are many possible
modes for governance in the area but given the
rapidity of change and the need for iterative, agile and
responsive guardrails, it is our recommendation that
Responsible Innovation approaches should be explored
in a more focused way. This gives rise to specic
recommendations in several areas.
It is our recommendation
that Responsible
Innovation approaches
should be explored in a
more focusedway
28
Creating a Responsible Quantum Future
Responsible Innovation Hub for quantum
computingtechnologies
For all the reasons given above, this report highlights the need for a central
responsible-innovation-focused resource. This Hub would be designed to
expand on the advisory role of the NQIT-RRI project that focused on Responsible
Innovation training and consultation and would operate as a central contact
for RI work in quantum computing, drawing together the various groups and
interests in quantum, for work encompassing:
· offering direct RI advice to projects and start-ups
· organising liaison work with stakeholders
· serving as a point of contact for policy
· improving understanding of responsible innovation among students,
researchers and early adopters
· anticipating and addressing some of the broader challenges that may
hinder adoption of responsible innovation mindsets
The research on which this report is based has demonstrated the need for a
much more in-depth approach to responsible innovation in quantum computing,
one that understands the commercialisation imperatives of the sector; the
investment needs; the governance options; the unique way in which much
quantum computing research is being carried out; the international context;
andthe options available to the UK in terms of its global positioning, as well as
the fundamentals of responsible innovation.
Such an approach must encompass actors across the triple helix, and, at
the conuence of academia and industry providing a core resource as part
of the UK National Quantum Strategy, we suggest that the new National
Quantum Computing Centre is a key player in this work. The details of this
involvement would be discussed with Directors of the NQCC if, as we hope, an
RI Hub is supported and resourced, but could include acting as a permanent
organisational locus for this work (actual physical presence is likely to be
minimal, with most work done remotely or at visits to companies and research
centres) and mediating between the RI Hub and early adopters and other
stakeholders. The Hub’s role would also encompass monitoring and recording
global developments in the implementation and societal impact of quantum
29
Creating a Responsible Quantum Future
information technologies and be a resource as a centre of expertise for policy
makers and other stakeholders. Alternative locations would also be feasible as
long as the Hub was ‘hosted’ by an organisation eligible for funding. The User
Engagement team of the QCS Hub also have an important role.
A roadmap for an RI Hub in quantum
Although further research would be required to create any detailed roadmapping
recommendations, certain milestones would stand out. These could include:
Key points on the roadmap would iterate or shift focus depending on the
development of the eld and the sector, but the general trend would be to embed
RI throughout the research, development and commercialisation process, while
also working with policymakers at national and international level to develop
coherent strategies for the ongoing development of QC. The roadmap does
Suggested roadmap for the development of RI in quantum computing
Advice and consultancy
with QC-adjacent
companies on RI
Now Creation of
RI capacity in the
NQTP/NQCC
Specialised RRI
training for all
students in QC
Using the framework
to continually
anticipate and
respond to RI
issuesin QC
Work with
policymakers
on coherent QC
approach
Rening
the AREA+
framework in the
QC context
Engaging widely
with stakeholders Future
30
Creating a Responsible Quantum Future
not have an end-point as such because the nature of carrying out responsible
innovation work means that it is never ‘done’ – rather it is an ongoing process
that develops as the technology develops. Mature technologies will have
different impacts and different requirements than during the growth period,
butoversight and responsiveness will still be required.
Investment
Signicant investment in the sector must come from government. Government
must be an early customer and also a supporter of the sector, working to
leverage private investment in the UK’s world-leading coherent innovation
ecosystem. In this regard it is important to learn from the past – for example
with respect to AI and large technology companies – in allowing a small number
of very large companies to dominate a sector, with all the associated challenges
of security, governance and resourcing that that can create. This means,
among other considerations, the need to balance the needs of large incumbent
corporations against the challenges for specialised SMEs. Participation in
the sector demonstrates not just government condence in the value of UK
expertise, but also ensures that the UK retains the skills of those working in
it, offers reassurance to other investors, and provides opportunities for soft
governance techniques that can ensure responsible innovation approaches
are embedded throughout. Such an investment strategy would need to be both
granular and detailed to provide support of the appropriate kind at various levels.
Horizon planning, not scanning
Exercises in trying to anticipate the future, often known as horizon-scanning, may
be of limited usefulness in fast-moving sectors with many variables as there are
too many uncertainties for it to be possible to create realistic predictions. However,
a more proactive and constructive, anticipatory governance approach can plan
and work towards particular outcomes whilst simultaneously retaining the
capacity to respond to events. Currently the quantum computing sector is moving
extremely fast, but it remains possible for proactive planning to steer its direction,
for example, through choices around distribution of funding, prioritisation,
decisions around export licences and so on. This need to make active choices
about a future that is being planned for and worked towards goes beyond simple
horizon-scanning about what may be approaching and is best implemented at a
policylevel.
31
Creating a Responsible Quantum Future
Stakeholder input
The potential importance of the quantum computing sector to the UK economy,
as well as the potential impacts in terms of (for example) security, makes it
imperative to incorporate as many different viewpoints as possible into any
policy approach. The challenges of nancing small quantum start-ups, for
example, may be rendered signicantly greater by the exigencies of the National
Security and Investment Bill – however, the security concerns that led to the
genesis of the Bill are also signicant. These are balances and trade-offs that
have implications for trusted and responsible innovation approaches because –
as previously discussed – ‘soft’ governance such as RI is more agile, has greater
adaptability, and can encompass areas of action that are difcult to incorporate
into legislation. There is, therefore, a clear need to incorporate multiple
stakeholder viewpoints and needs into governance. This is a task that would be
regarded as a priority for the RI Hub.
International viewpoint
In particular, the UK must participate in global discussions on quantum
governance, which should not be limited to the creation of a level playing eld in
industry or denitions of terms. Given the global, systemic nature of both hard
infrastructure such as internet communications and soft infrastructure such
as nancial markets, no single entity, whether a government or a company,
should be ‘setting the pace’ of governance. The UK has an opportunity to lead on
anticipatory governance for quantum – and given the size of the UK programme
and its potential signicance, it is vital to hear from diverse voices to ensure that
the UK response brings societies and communities along with it.
32
Creating a Responsible Quantum Future
Conclusions
As quantum computing emerges from the laboratory to become a potentially
disruptive and transformational technology in a number or elds, a Responsible
Innovation approach is increasingly urgent if the benets are to be maximised
and any social challenges are to be anticipated and addressed. We propose a
Responsible Innovation Hub for Quantum Computing, a small but adequately
resourced centre of expertise to catalyse RI awareness and activity in ongoing
research and in the emerging QC innovation community. We envisage working
closely with the National Quantum Computing Centre, alongside the Quantum
Computing and Simulation Hub, as key actors in the UK QC ecosystem.
Responsible Innovation aims not only to meet societal challenges but, as a
resource for creative thinking, to lead to the development of innovations and
technologies that are likely to be embraced by the public and enjoy greater
commercial success, and to maintain the UK’s world-leading position in the
emerging multi-billion-point quantum computing market while strengthening
international research and co-operation.
33
Creating a Responsible Quantum Future
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... The huge surge in both the quantity and the type of private investment represents a further challenge for governance. Government support has been called for in previous work to ensure that private capital does not 'capture' the quantum computing sector (eg Ten Holter et al., 2021a), but the degree to which public sector funding is now outweighed by private funding represents not just a loss of public representation in the sector, but a reduction of the proportion of funding that is attended by relatively stringent governance requirements around research. However, there is potentially an opportunity to improve governance structures in privately-funded work due to the use of 'evergreen' funds that reduce the pressure for rapid returns on investment -there may be time and space to permit of greater reflection and anticipatory governance approaches. ...
Thesis
Full-text available
This thesis investigates the value and effectiveness of anticipatory governance techniques in a new technology – in this case, quantum computing. It contributes a novel framework to encourage more widespread institutionalisation, translational capability, and ease of use for such anticipatory governance methods. Novel technologies frequently have (and indeed are expected to have) societal impact – quantum computing is one such technology. However, technologies that can have societal impact need to both merit and retain societal trust – such trust is predicated upon reliable and responsible methods of development, which enable publics to be assured of both specific and systemic trustworthiness. These concepts are closely allied to governance – but in the case of fast-developing technologies, there is often not yet any ‘traditional’ form of governance such as regulation. Traditional forms of governance are generally reactive, waiting for harm to occur before being framed. This is contrasted with ‘anticipatory’ governance, which seeks to mitigate potential negative outcomes by involving stakeholders in developmental processes, empowering researchers and developers to reflect on potential outcomes and consequences, and enabling them to respond in ways that can reduce harmful societal impacts. This thesis has investigated these topics through qualitative case studies and analysis in three key domains for quantum computing – industry, academia, and policy. The work has engaged with leaders and significant figures across these sectors, drawing out themes that are specific to quantum computing as well as those that are commonly encountered across computer science disciplines, and some that are found in all novel technologies. As a result of these investigations, it has developed a Framework that can be used for anticipatory governance purposes across research, industry, and in policymaking. The thesis closes by describing how the Framework has been demonstrated and evaluated in numerous contexts; addressing and elaborating on some of the persistent underlying themes that have emerged through the work; and suggesting avenues for further research.
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