Re-examining Orkney: a barium–rubidium and lithofacies screen of the Eday Group and outer islands as a candidate source for the Stonehenge Altar Stone
Third
in a sequence applying the Screening the Orcadian Basin method (Daw 2026) to
candidate ground beyond the primary study area
sarsen.org Altar Stone Sourcing Enquiry ·
working paper · 12 July 2026
Abstract
Bevins et al. (2024) excluded Mainland
Orkney as the source of the Stonehenge Altar Stone on the basis of a limited
set of Stromness- and Rousay-Flagstone field samples, leaving the outer islands
and the Eday Group untested. We re-examine Orkney comprehensively, combining
the barium–rubidium stream-sediment screen of Daw (2026) with a lithofacies
analysis of the Eday Group and a re-reading of the one published Eday
clay-mineral datum, and we test the specific fault-controlled high-barium
corridors on Sanday that a parallel desktop analysis proposed as candidate
ground. Orkney returns essentially no signal on the primary screen: a 0.03%
barium-floor hit rate against 10.8% for the mainland Orcadian outcrop — a
single cell, at Yesnaby, independently attributable to vein baryte. The
proposed Sanday corridors fall below both the barium floor and the ratio
threshold and do not register. On lithofacies, Sanday and the coarse Eday
Sandstone are disqualified: the only Altar-Stone-compatible facies, the Eday
Flags, thins northward from about 150 m at Deerness and South Ronaldsay to
roughly 10 m of flaggy sediment on Sanday and the Calf of Eday, where the
succession is dominated by coarse, pebbly, cross-bedded sandstone. The sole
facies-plausible residual — the Eday Flags of Deerness and northern South
Ronaldsay — is not a screen hit, shows no elevated barium consistent with the
Altar Stone’s diagnostic baryte cement, lacks tosudite (absent from every
Orkney sample measured), and remains gated on an untested Eday-Group detrital-zircon
comparison. We conclude that the screening process does not identify Orkney as
a candidate source. The result is independent of, and consistent with, the
Bevins mineralogical exclusion, and extends it to the outer-island gap that
direct sampling had not reached.
1. Introduction
Clarke et al.
(2024, 2026) established, from detrital-zircon and apatite/rutile U–Pb
geochronology, that the Altar Stone’s detritus derives from the Orcadian Basin
of northern Scotland. Bevins et al. (2024) then tested Mainland Orkney
directly, using portable XRF, automated SEM-EDS mineralogy, and clay X-ray
diffraction on field samples of the Stromness and Rousay Flagstone formations,
and concluded those units do not match the Altar Stone — principally on their
abundant detrital K-feldspar, the absence of the pervasive diagenetic baryte
cement that characterises the stone, and the absence of its diagnostic tosudite
clay. That is a well-evidenced exclusion of the sampled units. It does not, by
itself, speak to the Orkney ground that was not sampled: the outer islands, and
in particular the Eday Group, which crops out most fully on Eday and Sanday and
only marginally on the Mainland localities Bevins examined.
This paper
closes that gap. It is the third in a sequence that applies the desk-based
barium–rubidium screen of Daw (2026) — developed to rank the Orcadian Basin,
and extended nationally in that paper’s Appendix C — to candidate ground the
primary study set aside. The first established East Caithness (near Sarclet,
and the Lybster–Clyth flagstone coast) as the strongest candidate,
independently corroborated by the Clarke zircon match. The second closed the
Midland Valley of Scotland. Here the method is turned back on Orkney, prompted
by a parallel desktop analysis that proposed a set of fault-controlled,
high-barium corridors on Sanday — in the Upper and Middle Eday Sandstone, near
the North Scapa Fault and the Cata Sand system — as a previously untested Orkney
target. We assess those corridors, and Orkney more generally, on the same two
axes the method rests on: stream-sediment geochemistry, and lithofacies.
2. Data and methods
The
geochemical screen is that of Daw (2026): a basin-relative composite condition
on the BGS G-BASE 500 m kriged stream-sediment grids — a barium floor (1025
ppm) combined with a barium/rubidium ratio threshold (the 95th percentile, ≈
14) — with each surviving cell bedrock-verified by point-in-polygon join
against the BGS Geology 625k map. Rubidium substitutes for potassium and so
tracks K-feldspar and mica; the ratio isolates the Altar Stone’s distinctive
combination of high barium (baryte cement) with a deficit of K-feldspar. Two
limits of the method are load-bearing here and are stated at the outset. First,
stream-sediment values are not rock values, and cannot be compared directly
against the Altar Stone’s measured rock geochemistry; the screen is calibrated
against stream-sediment thresholds only. Second, formation identity is not
facies identity: a cell on genuine Old Red Sandstone bedrock may still be the
wrong lithofacies, so a geochemical hit is a necessary but not sufficient
condition and must be read together with the sedimentology.
The
lithofacies analysis draws on the regional survey of Mykura (1976), after the
sedimentological work of Fannin (1970) and Ridgway (1974), which maps the Eday
Group and its internal thickness variation along the 58 km north–south outcrop.
The clay-mineral comparison uses Table 4 of Bevins et al. (2024); we re-read
the single Eday Group entry (sample 5514) directly from the published table
image, because a flattened transcription of that row misassigns its values
(Section 4.4).
3. Results
3.1 Orkney is effectively silent on the primary
screen
On the barium
floor alone, the Orkney archipelago returns a 0.03% hit rate against valid grid
cells — a single cell, at Yesnaby, itself independently attributable in the
literature to vein-hosted baryte rather than diagenetic cement — against 10.8%
for the mainland Orcadian outcrop (Caithness, Sutherland, Moray, Black Isle)
and 2.8% for Shetland: a roughly 350-fold contrast between Orkney and the
mainland basin. Under the full composite condition, no Orkney cluster survives.
The Deerness area of East Mainland and the island of South Ronaldsay — which,
as Section 3.3 shows, carry the only Altar-Stone-relevant facies — both fall
within this near-zero population. There is no Orkney screen hit to rank.
3.2 The proposed Sanday corridors fall below
threshold
The parallel
analysis reported its strongest Sanday barium pixels at roughly 670–675 ppm
with barium/rubidium ratios of about 8.5–8.9. Both figures sit below the
screen’s thresholds — the barium floor of 1025 ppm and the ratio threshold of
about 14 — by a clear margin. On the method’s own terms these are not
anomalies; they are ordinary background, and they do not register. The
corridors were interpreted as fault-controlled secondary baryte along the North
Scapa Fault trend, which is the same vein-baryte association that makes the
single Yesnaby cell a documented false positive rather than a candidate. We
note one mitigating caveat, developed in Section 4.3: Orkney is extensively
covered by blown sand and till, and its G-BASE coverage is sparser than the mainland,
so a stream-sediment null over Orkney is softer evidence than a null over open
mainland ground.
3.3 Lithofacies: the fine facies has pinched out
in the north
The Eday
Group is roughly 1,000 m of dominantly fluvial sandstone (Lower, Middle and
Upper Eday Sandstone), with red marls and two finer intervals; of its
formations, only the Eday Flags contain the lacustrine, finely laminated, grey
‘quiescent-water’ facies that resembles the fine, well-sorted, ripple-laminated
Altar Stone. Mykura (1976) maps the thickness of the Eday Flags along the whole
outcrop, and the gradient is monotonic: thick in the south, effectively gone in
the north.
The proposed
Sanday corridors sit in the bottom row, and in the coarse Middle/Upper Eday
Sandstone rather than the Eday Flags. On Sanday the Middle Eday Sandstone alone
reaches some 400 m of reddish-purple, trough-cross-bedded, pebbly gritty
sandstone, with conglomerates at Hegglie Ber — a fundamental lithofacies
mismatch to the Altar Stone. The one fine interval on the island, at roughly 10
m, is too thin and too sandy to source a coherent monolith of the required
dimensions, and is untested. Sanday, the Calf of Eday, and the fault-proximal
Eday ground (where, along the North Scapa Fault, the Flags horizon passes
entirely into sandstone) are therefore closed on facies.
3.4 The Eday Flags residual is not
screen-supported
The
lithofacies analysis leaves a single facies-plausible residual: the Eday Flags
where they are thick and best developed, at Deerness and northern South
Ronaldsay. This ground is not, however, a product of the screen — it carries no
elevated barium (Section 3.1). Since the Altar Stone’s defining diagnostic
feature is its pervasive baryte cement, which is precisely what generates a
high-barium signal, the absence of any barium anomaly over the fairway is at
best neutral and arguably mildly counter-indicative: it suggests the baryte
cement is not developed in these Eday Flags. Bevins et al. (2024) found no
diagenetic baryte in any Orkney sample, consistent with that reading.
3.5 Clay mineralogy: a partial match, missing the
diagnostic phase
The only
published Eday Group clay analysis is Bevins et al. (2024) sample 5514, from an
undivided Eday Group exposure at Bu 1 on southern Mainland — not from the
Sanday corridors, and not from the Deerness/South Ronaldsay fairway. Read
directly from the table, its <2 µm assemblage is about 10% illite, 49%
R1-ordered mixed-layer illite/smectite (expandability ~25%), and 41% kaolinite,
with no tosudite and no dioctahedral chlorite. Against the Altar Stone (illite
14–19%, dioctahedral chlorite 12–13%, tosudite 15–21%, R1 I/S 26–33%, kaolinite
16–25%), this is a partial match: it shares the kaolinite and the R1-ordered
illite/smectite — the closest any Orkney sample comes to the stone — but lacks
the tosudite and dioctahedral chlorite that are the Altar Stone’s diagnostic
phases. Tosudite is absent from every Orkney sample Bevins et al. measured.
4. Discussion
4.1 Closing Orkney on the right grounds
It is worth
being explicit about why Orkney closes, because the parallel analysis reached a
superficially similar conclusion by arguments that do not hold. It compared a
Sanday stream-sediment barium/rubidium ratio (≈8.6) against an Altar Stone
rock-level ratio (≈105), an invalid cross-medium comparison that would equally
‘exclude’ the corroborated East Caithness lead (stream-sediment ratio 18.2); it
invoked a basin-wide thermal ceiling to argue tosudite could not survive, an
argument that would also exclude the Caithness flagstones, where tosudite is
likewise unreported; and it rested partly on a clay transcription that
misassigned sample 5514’s values (Section 4.4). None of those arguments is
needed, and none is sound. The defensible closure is simpler and independent of
them: Orkney produces no screen signal (Section 3.1–3.2), and the coarse Eday
facies that the barium corridors actually sample is the wrong rock, while the
only compatible facies has pinched out in the north (Section 3.3).
4.2 The residual, and the gate that remains open
Intellectual
honesty requires that the Deerness/South Ronaldsay Eday Flags be recorded as a
residual rather than a closed case. It is the one Orkney ground that is the
right facies and carries a partial clay match. But it is a facies-and-clay
inference the geochemistry does not support, and it is gated on a
detrital-zircon question that has not been answered. The Eday Group is
stratigraphically higher than the Stromness/Rousay flags on which Clarke’s
Orcadian match was established, and it was fed from the south and south-west
carrying rhyolitic and volcanic detritus, with contemporaneous Middle-Devonian
volcanism at the base of the Eday Flags. Its provenance therefore cannot be
assumed to reproduce the Altar Stone’s signature merely because it lies within the
basin — the same reasoning that governed the Midland Valley Upper Old Red
Sandstone. A young or distinct volcanic zircon population, if present, would be
inconsistent with the Altar Stone’s youngest concordant grain of ~498 Ma.
Resolving whether any Eday Group detrital-zircon dataset exists, and how it
compares, is the one desk check that could either close this residual outright
or promote it to a field target; until then it is untested, not eliminated.
4.3 The drift-cover caveat
A
stream-sediment null over Orkney is weaker evidence than the same null over
open mainland ground. Orkney carries extensive blown sand and till — Sanday
especially, with the Cata Sand system — and its G-BASE sampling is
correspondingly sparser, so the grid may in places be sampling superficial
cover rather than bedrock. This is a genuine reason not to treat the Orkney
null as a hard exclusion. It is not, however, a reason to read the null as
encouragement: the absence of a barium signal remains consistent with the
mineralogical absence of baryte cement that Bevins et al. measured directly,
and the lithofacies closure of Sanday (Section 3.3) does not depend on the
geochemistry at all.
4.4 Relation to Bevins et al. (2024)
This
re-examination is independent of the Bevins exclusion — it uses different data
(national stream-sediment geochemistry and regional lithofacies rather than
local field mineralogy) — and reaches a consistent result by a different route.
Where Bevins et al. excluded the sampled Mainland flagstone units on
mineralogy, the present screen finds no Orkney signal at all, and the
lithofacies analysis accounts for the outer-island Eday Group that direct
sampling had not reached. The two lines together close the outer-island gap
that the original Orkney rejection had left open, with the single, explicitly
flagged residual of Section 4.2.
5. Conclusion
Applied
comprehensively to Orkney — including the previously untested outer islands and
the specific fault-controlled corridors proposed on Sanday — the screening
process does not identify a candidate source for the Altar Stone. Orkney is
effectively silent on the barium–rubidium screen (a single vein-baryte cell
against a 350-fold-higher mainland hit rate), the Sanday corridors fall below
threshold, and Sanday together with the coarse Eday Sandstone is disqualified
on lithofacies, the only Altar-Stone-compatible facies having thinned to a
marginal remnant in the north. The sole residual, the Eday Flags of Deerness
and northern South Ronaldsay, is facies-plausible but unsupported by the
geochemistry, without the Altar Stone’s baryte cement or tosudite, and gated on
an untested Eday-Group zircon comparison; it is recorded as untested rather
than eliminated. This is a negative result, and a useful one: it removes Orkney
from contention on the method’s own terms and, with the Anglo-Welsh Basin and
the Midland Valley, leaves the enquiry’s signal concentrated where the screen,
the lithofacies, and the independent zircon evidence agree — the East Caithness
coast of the mainland Orcadian Basin.
Selected references
Bevins, R.E. et al.
(2024). Was the Stonehenge Altar Stone from Orkney? Investigating the
mineralogy and geochemistry of Orcadian Old Red sandstones and Neolithic circle
monuments. Journal of Archaeological Science: Reports, 58, 104738.
Clarke, A.J.I. et al.
(2024). A Scottish provenance for the Altar Stone of Stonehenge. Nature.
Clarke, A.J.I. et al.
(2026). From Highlands to Henge: Refining the Provenance and Transport Pathways
of Stonehenge’s Altar Stone. Journal of Quaternary Science.
Daw, T. (2026). The
Stonehenge Altar Stone: Screening the Orcadian Basin. sarsen.org / repository.
Fannin, N.G.T. (1970).
The sedimentary environment of the Old Red Sandstone of western Orkney. PhD
thesis, University of Reading (unpublished).
Hillier, S., Wilson,
M.J. & Merriman, R.J. (2006). Clay mineralogy of the Old Red Sandstone and
Devonian sedimentary rocks of Wales, Scotland and England. Clay Minerals, 41,
433–471.
Mykura, W. (1976).
British Regional Geology: Orkney and Shetland. HMSO, Edinburgh.
Ridgway, J.M. (1974).
The Sedimentology and Palaeogeography of the Eday Group, Middle Old Red
Sandstone, Orkney. PhD thesis, University of London (unpublished).
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