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Scholars have long seen in the monumental composition of Stonehenge evidence for prehistoric time-reckoning—a Neolithic calendar. Exactly how such a calendar functioned, however, remains unclear. Recent advances in understanding the phasing of Stonehenge highlight the unity of the sarsen settings. Here, the author argues that the numerology of these sarsen elements materialises a perpetual calendar based on a tropical solar year of 365.25 days. The indigenous development of such a calendar in north-western Europe is possible, but an Eastern Mediterranean origin is also considered. The adoption of a solar calendar was associated with the spread of solar cosmologies during the third millennium BC and was used to regularise festivals and ceremonies.
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Research Article
Keeping time at Stonehenge
Timothy Darvill*
* Department of Archaeology and Anthropology, Bournemouth University, UK (tdarvill@bournemouth.ac.uk)
Scholars have long seen in the monumental compo-
sition of Stonehenge evidence for prehistoric time-
reckoninga Neolithic calendar. Exactly how such
a calendar functioned, however, remains unclear.
Recent advances in understanding the phasing of
Stonehenge highlight the unity of the sarsen settings.
Here, the author argues that the numerology of these
sarsen elements materialises a perpetual calendar
based on a tropical solar year of 365.25 days. The
indigenous development of such a calendar in
north-western Europe is possible, but an Eastern
Mediterranean origin is also considered. The adop-
tion of a solar calendar was associated with the spread
of solar cosmologies during the third millennium BC
and was used to regularise festivals and ceremonies.
Keywords: Britain, Wessex, Stonehenge, solar calendar, time-reckoning
Introduction
Located on the chalk downlands of southern Britain, Stonehenge has long been thought to
incorporate some kind of calendar, although its specic purpose and exactly how it worked
remain far from clear. At the beginning of the twentieth century, Lockyer (1909: 47377)
proposed that the monument represented a May Calendarbased on clock-stars. Later,
Hawkins (1965: 11617 & 17481) advanced its interpretation as a Neolithic computer,
aligned to eight extreme positions of the sun and moon, for the purposes of time-reckoning
and predicting eclipses. Thom (1967: 10717), meanwhile, favoured a calendar of
16 months, using the solstices, equinoxes, May/Lammas and Martinmas/Candlemas as turn-
ing points in the cycle. These and many other interpretations, however, are all unsatisfactory,
as they often use non-contemporaneous elements of the monument, reference astronomical
alignments that do not withstand close scrutiny (Ruggles 1997: 203), or perpetuate the dis-
credited idea of a Celtic Calendar(Hutton 1996: 40811).
Recent remodelling of the developmental sequence at Stonehenge shows that the three
sarsen structuresthe Trilithons, Sarsen Circle and the Station Stone Rectangleall belong
Received: 16 May 2021; Revised: 5 September 2021; Accepted: 20 October 2021
© The Author(s), 2022. Published by Cambridge University Press on behalf of Antiquity Publications Ltd. This is an
Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.
org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the
original work is properly cited.
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to Stage 2 and were set up during the period 26202480 BC (Darvill et al.2012: tab. 3; Dar-
vill 2016). Once in place, these components were not moved or changed, and their integrity
is further supported by analysis showing that most of the stones derive from a single source on
the Marlborough Downs (Nash et al.2020). Understanding the sarsen elements as a unied
group and recognising the numerical signicance of the elements in each component opens
up the possibility that they represent the building blocks of a simple and elegant perpetual
calendar based on the 365.25 solar days in a mean tropical year. Here, I examine the evidence
at Stonehenge to suggest how such a time-reckoning system might have worked, going on to
address the question of its origins and development, and to ask why such a calendar might be
materialised in the architecture of this exceptional monument.
Building time into the fabric of Stonehenge
The ensemble of sarsen structures at Stonehenge is unique in north-western Europe; in terms
of its design and construction, it resembles no other stone monument of the mid-third mil-
lennium BC. The three main components described briey below sit astride a central axis.
The Sarsen Circle
The most visually prominent structure at Stonehenge is the ring of 30 upright sarsen stones,
linked at the top with 30 lintels (Figure 1). The uprights are conventionally numbered
S(tone)1 to S30 in clockwise fashion, starting at the north-east. Seventeen of the uprights
are still standing in their original positions, seven are extant but fallen and six are missing.
Six lintels remain in place atop their supporting uprights, while two fallen examples lie on
the ground; 22 are missing. Although the missing stones have sometimes been suggested
to indicate that the Sarsen Circle was never completed (e.g. Ashbee 1998), sockets for
some fallen or missing uprights are known through excavation (Cleal et al.1995: 192
Figure 1. Stonehenge, viewed from the north-east, showing the post-and-lintel construction of the Sarsen Circle
(photograph by T. Darvill).
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94), and the positions of the others are known through parch-marks recorded in 2013 (Ban-
ton et al.2014:g. 1). Moreover, constructional features relating to the method for tting the
stones together, as revealed by eld examination and photogrammetric survey, provide evi-
dence of an intention to form a compete circuit (Field et al. 2015: 135). As such, it must
be concluded that the missing sarsen uprights and lintels were robbed in antiquity.
The extant Sarsen Circle demonstrates the intricacyof its construction. The spacing of the
pillars is fairly regular, but the gap between S1 and S30 to the north-east is larger than average,
at 1.38m, suggesting that this was an entrance; as S15 is missing, it is difcult to judge
whether there was a correspondingly wide gap to the south-west. Most of the uprights are
uniform in shape and size, the standard widthbeing approximately 1.9m, measured
1.5m above ground level. Two uprights, however, stand out. S11 (Figure 2) in the south-
Figure 2. Sarsen stone S10 (left) in the Sarsen Circle, with the small-sized S11 to the right. View looking outwards from
inside the circle. Scale = 2m (photograph by T. Darvill).
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eastern sector is notably narrower, at 1.1m wide; it is also thinner and shorter than most,
although recent work suggests that its top has been broken off (Abbott & Anderson-
Whymark 2012: 50). S21 (Figure 3) in the western sector appears complete but is narrower,
at 1.5m wide, and thinner than average. Figure 4 shows the pattern of stone widths and gaps
around the circumference of the Sarsen Circle. Although the six missing uprights lie in the
south-western sector of the circle, the size of their socketsknown through excavation or
parch-markssuggest they were standard widthstones. Counting sun-wise from S1,
there seem to be three distinct groups of ten uprights: S110, S1120 and S2130. Each
group is preceded by a slightly wider-than-usual gap, with S11 and S21 standing out due
to their smaller size.
Figure 3. Small-sized sarsen stone S21 (left) in the Sarsen Circle, with the normal-sized S22 to the right. View looking
outwards from inside the circle. Scale = 2m (photograph by T. Darvill).
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Figure 4. Plot showing the spacing and size of stones forming the Sarsen Circle (gure by T. Darvill).
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All the extant stones have been shaped and dressed. Through either selection or modi-
cation, most widen towards the top in a type of entasis to create the optical illusion of straight-
sidedness (Atkinson 1979: 37; but see Abbott & Anderson-Whymark 2012:2122). The
height of the uprights varies around the circumference in order to account for the natural
slope on the ground, ensuring that the ring of lintels is level. The lintels are secured to the
uprights with hemispherical protuberances and corresponding hollows known as stub-tenon
jointsa distinctive method, as the mortice holes into which the tenons t do not extend
through the full thickness of the lintels. Tongue-and-groove joints lock the ends of the lintels
together in a continuous ring.
The Trilithon Horseshoe
Inside the Sarsen Circle are ve sarsen trilithons arranged in a horseshoe shape that opens to
the north-east. All stones survive on site, although some have fallen. The south-western tri-
lithon (comprising uprights S55 and S56, and lintel S156) is the tallest and largest; the others
reduce in height towards the north-east, giving both vertical and horizontal emphasis to the
south-western trilithon. All the stones of the Trilithon Horseshoe have been shaped and
dressed, with stub-tenon joints securing the lintels to the uprights. Whittle (1997: 155
61) observed an alternating rhythm to the dressing and shaping of the uprights, with one
stone in each pair smooth and sharply dressed, while the other is rougher and more natural
in appearance (Figure 5).
Station Stone Rectangle
Outside the Sarsen Circle is a rectangular setting of four Station Stones. Only two survive:
S91 at the north-east corner (Figure 6) and S93 at the south-west corner (Figure 7), although
empty sockets representing the other two (S92 and S94) are known through excavation (Cleal
et al.1995: 273). Together, these four stones dene a relatively precise rectangle measuring
80 × 30m. Lines representing the two long sides would pass close to the outside faces of
stones S1/S30 and S15/S16 on the outer circumference of the Sarsen Circle. The Station
Stones are much smaller than the other sarsens and they are minimally dressed.
The Stonehenge axis
Embedded into the footprint and architecture of all three sarsen elements is a single, coherent
astronomical axis: a line orientated north-east to south-west. This line joins the points on the
locally visible horizons where the sun rises during the summer solstice to the north-east and
sets during the winter solstice to the south-west. This is the only major alignment embedded
in the architecture of Stonehenge, although Daw (2015) has argued that the positioning of
the south-western trilithon incorporates a closely related secondary solstitial axis based on the
skyline positions of the rising midwinter sun to the south-east and the setting midsummer
sun to the north-west.
The principal axis runs through the entrance to the Sarsen Circle, which is anked by S1
and S30 on the north-east side, and between S15 and S16 on the south-west side. The Tri-
lithon Horseshoe sits symmetrically astride the axis. The two short sides of the Station Stone
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Figure 5. Trilithon S53 and S54, with lintel S154, showing contrasting pairs of smoothed and rough uprights. View
looking outwards from the inside of the Trilithon Horseshoe (photograph by T. Darvill).
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Rectangle run parallel to the principal axis, albeit displaced to the north-west and south-east.
Ruggles (1997: 21821) has suggested that the two long sides of the rectangle are approxi-
mately orientated on major extreme moonrise positions, but whether deliberately or by
chance remains unclear.
Beyond the central settings, the principal axis is perpetuated by two stones positioned in
the entrance through the earlier earthwork enclosure, the Heel Stone (S96) and its
now-missing companion (S97), and by the embanked Avenue that was added in Stage 3
(Darvill et al.2012: 1035).
Time-reckoning
How do the elements of this ensemble t together as the physical expression of a calendar and a
mnemonic for its operation? A system based on the cycles of the moon is feasible but reconciling
the observable pattern of lunar months of 29 or 30 solar days with the solar year that structures
the seasons and human daily routines has posed a challenge for agrarian societies across time and
space (Nilsson 1920: 26781; Thorpe 1981: 27778). At Stonehenge, the emphasis on the sol-
stices embedded into the architecture in the form of the principal axis and its orientation strongly
suggests a solar-based system. The period between the recurrence of either one of these solstitial
events is, in practical terms, a tropical year of 365.25 solar days. With this gure in mind, the
numerology of the three sarsen structures comes together neatly as a tropical year (Figure 8).
Figure 6. Surviving Station S91 at the north-east corner of the Station Stone Rectangle (photograph by T. Darvill).
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The core of the year is represented by the Sarsen Circle. Here, each of the 30 uprights repre-
sents a solar day within a repeating 30-day month. Running sun-wise from the main axis, with
S1 representing Day 1, S11 and S21 become signicant, as they divide the month into three
weeksor decans, each of10 days; the anomalous stonesmark the startof the second and third
decans. Twelve monthly cycles of 30 days, represented by the uprights of the Sarsen Circle,
gives 360 solar days. While no stones within the central setting can specically be identied
with the 12 months, it is possiblethat the poorly known stone settings in and around the north-
eastern entrance (Cleal et al. 1995:g. 156) somehow marked this cycle.
Completing the basic tropical year requires an additional ve days: an intercalary month of
days known in later calendars as epagomenal days. The ve components of the Trilithon
Horseshoe, situated prominently in the centre of the structure, t this role. Working from
the north-east, they grow incrementally in stature, with the tallestknown as the Great Tri-
lithon (S55 and S56, and lintel S156)to the south-west. We have no names for these days,
but they could represent signicant deities (Darvill 2006: 14445), the contrasting treatment
of the uprights noted by Whittle (1997: 15561) perhaps imparting some kind of leftright
symbolism. Adding the intercalary month gives 365 solar days.
Making the solar calendar a perpetual one, in which the days, decans and months keep
pace with the seasons and the movements of the sun to describe a tropical solar year with
accuracy, requires periodic adjustment, specically, the addition of one day every four
Figure 7. Surviving Station S93 at the south-west corner of the Station Stone Rectangle (photograph by T. Darvill).
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Figure 8. Summary of the way in which the numerology of sarsen elements at Stonehenge combine to create a perpetual
solar calendar. Non-sarsen elements have been omitted for clarity (drawing by V. Constant).
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years to create a leap-year of 366 solar days. The four Station Stones provide a means of keep-
ing tally so that a sixth day could be added to the intercalary month every fourth year.
Bringing these parameters into line with the accumulation of solar days, weeks and
months, and recognising the solstitial axis and a clear focus on the midwinter setting sun,
the basic shape of a Late Neolithic solar calendar emerges. Starting at the winter solstice
emphasised architecturally by the orientation of the Trilithon Horseshoe to the south-west
the year starts with the rst movement of the setting sun away from its most extreme south-
westerly setting point. New Years Day, or Month 1/Day 1 (the equivalent of 24 December in
the modern proleptic Gregorian calendar, or PGC) is physically symbolised by Stone 1. Six
months (18 decans or 180 solar days) later, Month 6/Day 29 (19 June PGC), is the start of
the summer solstice, whose ve days of standstill span the last three days of Month 6 and the
rst two days of Month 7 (1923 June PGC). Six months on again, Month 12/Day 30
(18 December PGC) marks the start of the intercalary month of ve epagomenal days, form-
ing the period of the winter solstice (1923 December PGC): the end of the old year. An
additional day would be added to the intercalary month every four years to keep the solstices
aligned with observations of the suns movements in relation to the principal axis of the
monument. Using the solstitial alignment ensures that the calendar was synchronised with
celestial movements and the changing of the seasons. Arranging the entire complex around
a principal axis might relate to processional movement, and a sense of order, sequence and
meaning played out in the way the site was used: a directional force with physical, visual
and emotional power.
Fragments of this prehistoric calendar can be found surviving into recent times. Hutton
(1996: 8) has delicately unpicked Christian and modern scholastic overlays to reveal the exist-
ence of a major pre-Christian festival marking the opening of the New Year, at the moment
at which the sun had reached the winter solstice and its strength was being renewed.One
important piece of supporting evidence is De temporum ratione, written c. AD 725 by the
Northumbrian monk and scholar Bede. This account records that the pre-Christian New
Year was marked by the midwinter festival of Yule; combined with a midsummer festival
known as Litha, the year was divided into two parts (DTR 15; Willis 1999:5354).
Using linguistic evidence, Mallory and Adams (2006: 302) reconstruct two words for
yearthat express the notion of new seasonin the proto-Indo-European language thought
to be current during the third millennium BC. At Stonehenge, the principal axis naturally
divides the monument and, by implication, the calendar it represents into two halves,
with both the winter and summer solstices clearly embedded in the architecture of the
structure.
Local innovation or external inuence?
It is entirely possible that communities living in north-western Europe during the late fourth
and third millennia BC developed a solar calendar of the type suggested here on their own
initiative. Evidence for the alignment of several passage graves, including, for example, New-
grange in Ireland and Maes Howe in Orkney, on celestial events during the winter solstice
may support this idea. The uniqueness of Stonehenge, however, prompts a pause for thought.
External inuences may also be possible, especially given contemporaneous developments
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3500km away in the Eastern Mediterranean. Here, during the fourth millennium BC, a var-
iety of lunar-stellar calendars used observational astronomy to reconcile the movements of the
moon and stars with the daily and seasonal cycles of the sun (Parker 1974; Sachs 1974). Dur-
ing the early third millennium BC, however, increased interest in solar deities, such as the cult
of Ra (Quirke 2001), led to the development in Egypt of a 365-day solar calendar, known as
the Civil Calendar. The origins, development and form of the Egyptian Civil Calendar have
been described in detail by Nilsson (1920: 27781) and Stern (2012: 12566). Just as at
Stonehenge, the calendar comprises twelve 30-day months, together with an intercalary
month of ve epagomenal days. The months are each divided into three weeks of 10 days.
The need for an additional day every four years to keep track with the seasons was understood,
although not implemented until much later (Parker 1974: 53). As an expression of the solar
cosmology, the 12 months were named after the constellations that form the signs of the
zodiac, and the epagomenal days were festivals celebrating the ve children of Geb (earth
god) and his sister-spouse Nut (sky goddess): Osiris, Horus, Seth, Isis and Nephthys (Spa-
linger 1995).
Back-calculations using the pre-existing lunar-stellar calendar suggest that the Civil Cal-
endar started in 2773 BC. Like the cult of Ra, with which it was closely associated, the
Civil Calendar was widely used during the Third Dynasty at the start of the Old Kingdom,
c. 2658 BC. By the Fifth Dynasty (c. 25002300 BC), the cult of Ra had become the state
religion, with rulers taking the title Son of Ra(Quirke 2001: 17).
Egypt was not alone in developing a solar calendar. Englund (1988: 122) has convincingly
shown that similar time-reckoning systems were being used in Mesopotamia by the late
fourth millennium BC, and their adoption in the Eastern Mediterranean might have been
more widespread at this time than previously realised. It was patently successful, as many
of its key features were adopted in later calendars (Stern 2012: 125).
Archaeologically, the question is whether the Egyptian Civil Calendar, or a variation
thereof, could have been known to communities living in southern Britain in the mid-third
millennium BC, and adopted by them. Barely a century ago, the answer would have been
resoundingly afrmative (e.g. Childe 1929). As diffusionist models crumbled and connec-
tions between the Mediterranean world and northern Europe were systematically uncoupled
to emphasise autonomous local development (Renfrew 1973:84108), such thinking
became deeply unfashionable. Now, however, the pendulum of interpretation is swinging
back in favour of long-distance contacts and extensive social networks. Tight radiocarbon
chronologies allow synchronicities to be recognised, while aDNA and isotope studies empha-
sise the nature and extent of population movements during the third millennium BC (Fur-
holt 2018; Armit & Reich 2021). Especially relevant here is the life-story of the Amesbury
Archer, who was buried 5km south-east of Stonehenge c. 2300 BC in a simple grave, accom-
panied by an extraordinary array of grave goods, including some from continental Europe.
Isotope analysis shows that he was born and raised in the Alps and moved to Britain as a teen-
ager (Fitzpatrick 2011:65166).
Wilkinson (2010:5960) has documented the growth of long-distance trade beyond
Egypts traditional borders, in all directions, during Early Dynastic times. Stone vessels pro-
vide the earliest secure evidence, dating to the early third millennium BC, of Egyptian exports
to Minoan Crete, on the south-eastern extreme edge of Europe, with scarabs present in Early
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Minoan contexts after 2300 BC (Warren 2009: 38490). From the early second millennium
BC, the ow of prestige objects and materials between the Eastern Mediterranean and nor-
thern Europe, and vice versa, is well recognised, although much debated (see Harding 1983:
4115, 2013: 37980). Amongst the earliest known imports to Britain is the large, red-glass
bead from the Wilsford G42 bowl barrow, located 2.3km south-west of Stonehengean
object probably made in Egypt in the early second millennium BC (Guido et al.1984).
The source of the much-discussed faience beads found in prehistoric British contexts may
also be worth revisiting, recalling Hardings(1983: 87) comment that all authorities accept
that the technology originated in the Near East; what is in question is the place of manufac-
ture of these beads.Working back beyond 2000 BC, the archaeological trail marked by vis-
ible imports goes cold, although circumstantial indicators may be relevant. Particularly
important here is the adoption of solar cosmologies across large areas of northern Europe dur-
ing the third millennium BC (Jones-Bley 1993; Kristiansen & Larsson 2005: 251319; Kaul
2017) and its connection with the social construction of time (Kristiansen 2008).
The unique architecture of Stonehenge in the contextof mid third-millennium BC north-
western Europe is also relevant. Post-and-lintel construction in stone, the use of stub-tenons
to secure lintels to uprights, and the understanding of entasis to create the optical illusion of
straightness, are all features found only in Egypt at that time (Arnold 2003). Although cir-
cular structures in Egypt are fewthe so-called Calendar Circlewith solstitial alignments
dating to the fth millennium BC at Nabta Playa being something of an exception (Malville
2015)the circle motif was symbolic of the sun and the cycle of time (Quirke 2001:
16167). The adoption of a circle as the physical expression of a calendrical cycle makes
good sense, and in the context of Stonehenge is potentially signicant, as it perpetuated exist-
ing local, indigenous traditions of building stone and timber circles extending back to before
3000 BC (Darvill in press).
Less secure, but tantalising nonetheless, is the garbled reworking of eleventh-century AD
oral traditions recorded by Geoffrey of Monmouth. In his History of the kings of Britain, Mon-
mouth records that Africa was the original source of the stones, which were taken rst to Ire-
land to form the gigantium chora (the GiantsRing) and then to Stonehenge (HKB viii.11;
Thorpe 1966: 196). Perhaps signicantly, the word chorea has a series of meanings in medi-
eval Latin, including references to the movement (dance/circle) of the heavenly bodies.
Why build a calendar?
Materialising a time-reckoning system in the structure and form of a major monument, with
all the effort implied in doing so, should come as no surprise, for it is a common practice
amongst non-literate and semi-literate societies. One only has to marvel at recent astronom-
ical clocks, such as the fteenth-century example on the Town Hall in Prague, Czechia, to see
the effort invested in creating grand public timepieces. Whether or not the Stonehenge cal-
endar was a local development or part of an imported cosmology, the crucial question is: why
construct a calendar at all? To address this, four aspects can be considered.
First is the routine of everyday life. Although archaeological accounts often rehearse the
notion that early farmers needed time-reckoning systems to know when to plant and
when to harvest, no self-respecting farmer needs to be told these thingstheir skill and
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experience dictates how they work the land. Where farmers do need guidance, however, is in
knowing when to celebrate the harvest festival for best effect, or when to please the gods with
their presence at key ceremonies. Hutton (1996: 427) reviewed 40 festivals recorded in Brit-
ain over recent centuries, and while many were modern inventions, he found a vigorous sea-
sonal, festive culture surviving from ancient times. These are not so much calendar festivals as
festivals whose timing has been calendarised: important events that serve as landmarks in time
(Nilsson 1920: 83).
Second, as Stern (2012: 53) has cogently argued, ancient calendars provided a way for pol-
itical elites to legitimise power: who makes time makes power (Meller et al.2021). Not only
did elites control people and life on earth, but they also controlled the cosmos by using epa-
gomenal days and leap-days to harmonise time with the workings of the universe. This idea
resonates with ethnographic work by Hayden and Villeneuve (2011) on the religio-political
context of astronomy and timekeeping amongst complex hunter-gatherer societies.
Third, time-reckoning systems give substance to conceptual cosmologies, so that the
received narratives could be understood in ways that structured behaviours and relationships.
As Helms (1988: 26667) explains, the acquisition of esoteric knowledge transcends geo-
graphical distance, with elites acquiring superior powers from more potent places to enhance
their own positions. At Stonehenge, a new interest in the cycle of the sun in the later third
millennium BC may have replaced earlier lunar ideologies, a transition seen physically in the
eastwards shift by ve degrees in the axis of the Stonehenge Stage 1 enclosure to the principal
(solstitial) axis in Stage 2 (Cleal et al.1995: 170). By combining the solar cycle and the nat-
ural cycle of life in monumental form, the days, weeks, months and years served to structure
ritual cycles of responsibility and obligation.
Finally, time-reckoning systems bring communities closer to their gods by ensuring that
events occur at propitious moments. Astrology was an important, though controversial, tool
in ancient medicine and healing rites. An accurate calendar was required to maximise effects
that depended on people being in the right place at the right time. Salt and Boutsikas (2005)
have argued that the primary purpose of early Greek calendars was to structure access to
Apollo and to know when to consult the oracle or engage in healing rituals at Delphi. Simi-
larly, Meyer (2019) has emphasised the relationship between nds of calendrical clepsydra
(water clocks), springs and healing rituals in Roman Britain. Elsewhere, I have argued that
the Bluestone elements at Stonehenge, imported to the site from west Wales, represent the
power of the place and were intimately connected with healing rituals (Darvill 2007). Ensur-
ing that healing ceremonies happened at the right time is why the very structure of Stone-
henge from Stage 2 onwards embedded a means whereby its user-communities could
literally make, mark and keep pace with time.
Conclusions
The Stonehenge calendar hypothesised here provides a workable and archaeologically
grounded solution to an age-old interpretation. It adds a new dimension to the multi-faceted
structure and its uses from Stage 2 onwards, providing a secure cosmologically referenced
framework for the observance of festivals, ceremonies and rituals that were the reason for
the monuments construction. The selection of the existing Stage 1 earthwork enclosure,
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which had formerly been used as a cemetery, as the site for this innovative development elicits
no surprise. The site was already part of a well-established ceremonial centre that was located
beside good communication routes, and was a prominent node within trading networks that
extended across Britain and beyond. Thinking more widely about the origins of the solar cal-
endar, its meanings and its ramications, now requires a detailed review of the connections
between early farming communities across the Old World during the third millennium BC.
Acknowledgements
In preparing this article, I would like to thank Katherine Barker, Julian Henderson, Heather
Sebire, Fabio Silva and Peter Warren for their help and guidance on various aspects of the
material assembled and discussed here; the nal text also benets from the comments
made by two anonymous reviewers.
Funding statement
This research received no specic grant from any funding agency or from commercial and
not-for-prot sectors.
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Keeping time at Stonehenge
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... In 2022, in an article entitled "Keeping time at Stonehenge", Timothy Darvill proposed that a solar calendar, with 30-day months, 10-days weeks plus five epagomenal days, was embodied into the erection of the Sarsen structures of the monument. "Recent remodeling of the developmental sequence at Stonehenge shows that the three sarsen structures-the Trilithons, Sarsen Circle and the Station Stone Rectangle-all belong to Stage 2 and were set up during the period 2620-2480 BC" (Darvill 2022, Darvill et al., 2012: Darvill, 2016. Therefore, the embodiment of a calendar happened around 2620-2480 BC. ...
... Darvill is also mentioning ancient Egypt: "External influences [at Stonehenge] may also be possible, … During the early third millennium BC, … increased interest in solar deities, such as the cult of Ra (Quirke, 2001), led to the development in Egypt of a 365-day solar calendar, known as the Civil Calendar. The origins, development and form of the Egyptian Civil Calendar have been described in detail by Nilsson (Nilsson, 1920) and Stern (Stern, 2012)" (Darvill, 2022). ...
... In Darvill, 2022, we find a reference to a period when in Mesopotamia and Egypt we have calendars associated with written texts. Being calendars based on numerals it seems reasonable to consider that they existed before the advent of writing, even if we have no written accounts of them. ...
Preprint
Full-text available
The discovery of the Diary of Merer (papyri Wadi al-Jarf) allows us to see the Egyptian calendar applied in a logbook. The diary is dated to the 26th year of reign of Khufu and describes Merer and his crew transporting the limestone blocks from the Tura quarries to Akhet Khufu, that is, the pyramid of Khufu (Old Kingdom). We find a calendar with 30-day months, 10-day weeks, five epagomenal days (Tallet, 2017) and Merer’s job adapted to the seasons of the year. Seasons and epagomenal days have names according to inscriptions on the east wall of the Tehne tomb of Nj-k'-'nh (Nikaiankh), end of Fourth Dynasty or early Fifth Dynasty. The Diary gives us an overall impression of extreme modernity in the logistics of ancient Egypt. And Merer looks like a person with a reputation for good timekeeping at Akhet Khufu.
... In 2022, in an article entitled "Keeping time at Stonehenge", Timothy Darvill proposed that a solar calendar, with 30-day months, 10-days weeks plus five epagomenal days, was embodied into the erection of the Sarsen structures of the monument. "Recent remodeling of the developmental sequence at Stonehenge shows that the three sarsen structures-the Trilithons, Sarsen Circle and the Station Stone Rectangle-all belong to Stage 2 and were set up during the period 2620-2480 BC" (Darvill 2022, Darvill et al., 2012. Therefore, the embodiment of a calendar happened around 2620-2480 BC. ...
... Darvill is also mentioning ancient Egypt: "External influences [at Stonehenge] may also be possible, … During the early third millennium BC, … increased interest in solar deities, such as the cult of Ra (Quirke, 2001), led to the development in Egypt of a 365-day solar calendar, known as the Civil Calendar. The origins, development and form of the Egyptian Civil Calendar have been described in detail by Nilsson (Nilsson, 1920) and Stern (Stern, 2012)" (Darvill, 2022). ...
... In Darvill, 2022, we find a reference to a period when in Mesopotamia and Egypt we have calendars associated with written texts. Being calendars based on numerals it seems reasonable to consider that they existed before the advent of writing, even if we have no written accounts of them. ...
Article
Full-text available
The discovery of the Diary of Merer (papyri Wadi al-Jarf) allows us to see the Egyptian calendar applied in a logbook. The diary is dated to the 26th year of reign of Khufu and describes Merer and his crew transporting the limestone blocks from the Tura quarries to Akhet Khufu, that is, the pyramid of Khufu (Old Kingdom). We find a calendar with 30-day months, 10-day weeks, five epagomenal days (Tallet, 2017) and Merer’s job adapted to the seasons of the year. Seasons and epagomenal days have names according to inscriptions on the east wall of the Tehne tomb of Nj-k'-'nh (Nikaiankh), end of Fourth Dynasty or early Fifth Dynasty. The Diary gives us an overall impression of extreme modernity in the logistics of ancient Egypt. And Merer looks like a person with a reputation for good timekeeping at Akhet Khufu.
... In Stage 1 (3,000-2,935 BC), a circular enclosure with a diameter of ca. 100 m and 56 pit holes was surrounded by a ditch flanked by a high bank inside and a low bank outside. The three sarsen structures, the horseshoe-shaped circle of five trilithons, the sarsen circle of uprights and lintels (Fig. 137), and the Station Stone Rectangle belong to Stage 2 (2,620-2,480 BC) (Darvill, 2022), while side ditches and ceremonial avenue 3 km long to the Stage 3 (2,470-2,280); over 200 ceremonial burials belong to the Stage 2. In the fourth, fifth, and sixth stages (2,280-520), the bluestones were rearranged to form a circle and an inner oval setting of bluestones. Later a ring of pits (Y Holes) was dug outside the sarsen circle, and eventually, a second ring of pits (Z Holes) was dug (Parker Pearson et al., 2011; Parker Pearson, 2022). ...
... Their role was instead based on explaining the universe to the people and, probably, giving spiritual meaning to the agricultural processes or healing. These technically advanced structures might serve, as in other, much later cases, religious practices in the form of ceremonies or festivals (Parker Pearson et al., 2006) associated with both the spread of solar cosmologies in the 3rd millennium BC (Darvill, 2022) and the emergence of a cast of priests. ...
... The most recent note is in an architectural study proposing 12 (30) divisional structures in the design of Stonehenge. [26] In India, Earth's orbital period was divided into a greater number of units, resulting in N = 12(30 2 ) = 10,800 units, known as "muhūrta," ...
... [1] [26] [42] [43] [44] From a more modern standpoint, the study also addressed viewpoints from Newton and Einstein, which deviated from the cyclic and signal-centric descriptions prevalent in ancient models. Leibniz proposed a relational concept for time and space, but his theses still utilized both inertial frames and time derivatives of displacement, both of which are not used in Rt relationalism. ...
... Rather, the alignments at both Durrington Walls and Woodhenge appear to have been shortlived, with the posts decaying or the sightlines becoming compromised by later constructions such as henge banks (Ruggles and Chadburn 2024: 109-111). Darvill (2022) has recently proposed that Stonehenge encapsulated key elements of a 365¼-day solar calendar in its architectural design. The basic argument is that there are 30 uprights in the sarsen circle, 5 trilithons and 4 Station Stones, and 30 x 12 + 5 = 365, with 4 representing the quarter. ...
Article
Full-text available
This short paper focuses on monuments in the Stonehenge landscape, including Stone­henge itself, with the aim of presenting a “modern” picture of these monuments and their astronomy that is consistent with the latest archaeological evidence. While the connection of Stonehenge and other nearby monuments to astronomy is recognized by UNESCO as part of the Outstanding Universal Value of the Stonehenge World Heritage site, the only specific manifestation of this that has achieved broad consensus among archaeologists is the solstitial sightlines, indicated by the main axes of the stone settings at Stonehenge and the multiple timber circles at Woodhenge and Durrington Walls Southern Circle. These sightlines —precise enough to pinpoint the solstice in space although not in time— seem to represent a specific development in this area around the mid-3rd millennium BC. We proceed to critique some recent papers by well-respected archaeologists proposing (i) that Stonehenge encapsulated key elements of a 365¼-day solar calendar in the numer­ology of its key features; (ii) that a “mega-circle” of huge pits, over 2km in diameter, was built around the same time as the stone circle at Stonehenge, centred on Durrington Walls Henge; and (iii) that two large pits were placed in the Stonehenge Cursus positioned on the summer solstice sunrise and sunset alignments as viewed from the Heel Stone. We present new evidence to counter (ii) and argue that all these ideas extrapolate well beyond the available evidence and fall foul of basic methodological considerations (e.g., regarding data selection) that have been well known to cultural astronomers since the 1980s. We finish with a discussion of some open questions. The first is whether Stonehenge and some nearby contemporary monuments might have been placed at locations already per­ceived as significant because of the approximately solstitial alignment of natural features. Another is how long the solstitial sightlines remained “operational” in the sense of being usable for actual observations, and what this implies for their interpretation —particularly for ideas of solstitial observances involving processions between the different monuments. Third is the possibility that the solstitial orientations evident at and around Stonehenge in the mid-3rd millennium BC might have derived from practices developed centuries earlier in southwest Wales, from which the Stonehenge bluestones were brought. A final question that remains largely unresolved is whether the lunar alignment of the Station Stone rect­angle at Stonehenge was indeed intentional and, if so, what was its purpose and meaning. Recent investigations have succeeded in casting some new light on the subject.
... Jones, 2013; Bueno, Barroso y Balbín, 2023. 7 Briard y otros, 1995Darvill, 2022; Moreno y Delibes, 2007. 8 Curdy y otros, 2022. ...
Chapter
Full-text available
The European megalithic structures have been understood as the receptacle of collective burials across the Atlantic façade since Neolithic times. Relationships between various architectural and symbolic manifestations found in these necropolises remain a contemporary subject of discussion in relation to their chronology and diachrony, architectural evolution, modes of use, interactions on a larger and smaller scale, origins, and final completion. It is generally considered that megalithic funerary sites throughout Europe had closer relations than previously assumed. The complexity of these relations surpasses basic mechanisms of maritime diffusion in favour of an integration of these stone structures within the social and symbolic networks of the late Prehistory in Europe.
... Por supuesto, no cuestiono la utilidad de la arqueoastronomía, aunque su uso requiere unos conocimientos muy específicos para evitar caer en especulaciones faltas de sustento, como muestra la rotunda crítica que han propiciado a Timothy Darvill (2022) dos reputados expertos en esta disciplina (Magli y Belmonte, 2023), a cuenta de la funcionalidad de Stonehenge. ...
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