Thursday, 2 July 2026

A Multi-Element Geochemical Screen, Verified Against Bedrock Geology, for the Source of the Stonehenge Altar Stone Within the Orcadian Basin

A Multi-Element Geochemical Screen, Verified Against Bedrock Geology, for the Source of the Stonehenge Altar Stone Within the Orcadian Basin

Tim Daw
ORCID: 0000-0002-6377-2177
Cannings Cross Farm, Wiltshire SN10 3NP, UK
tim.daw@gmail.com  •  www.sarsen.org

July 2026
This work is licensed under a Creative Commons Attribution 4.0 International License (CC BY 4.0). https://creativecommons.org/licenses/by/4.0/

Abstract

The Stonehenge Altar Stone has been reattributed from Wales to the Orcadian Basin of northeast Scotland (Clarke et al. 2024), with the sampled localities of Mainland Orkney subsequently excluded as its specific source (Bevins et al. 2024). The Orcadian Basin itself, however, extends from the Moray Firth to Shetland and remains largely unsampled beyond a small number of hand specimens. We conducted an independent, open-data desk screen of the entire basin using BGS G-BASE stream-sediment barium and rubidium grids (500 m resolution) cross-referenced, pixel by pixel, against the BGS Geology 625k bedrock polygon dataset. Screening on the Altar Stone's published barium floor (Bevins et al. 2023; >1025 ppm) combined with a basin-relative Ba/Rb ratio threshold, we identify two priority candidate areas: a 42.5 km² area of the East Caithness coast, centred approximately 10 km southwest of Sarclet (98% confirmed genuine Middle Old Red Sandstone), and Shetland (Melby/Walls, 85% confirmed). The East Caithness result independently converges, within roughly 10 km, with a peer-reviewed detrital zircon geochronology study (Clarke et al. 2026) that identified Sarclet itself as its strongest statistical match (p = 0.96) using entirely unrelated data, assumptions, and methods. We report two negative or partially negative refinements as part of the method (a fault-proximity discriminant that did not survive testing; an unresolved glacial-till provenance question) and provide full data provenance for independent replication, including independent replication of the core grid-screening component by a separate AI system.

1. Introduction

The Altar Stone is the central sandstone megalith at Stonehenge, a six-tonne block long assumed, on stylistic grounds, to share the Anglo-Welsh Basin origin of the site's other non-sarsen ‘bluestones’. Clarke et al. (2024) overturned this using detrital zircon and apatite U–Pb geochronology, showing the Altar Stone's age spectrum matches the Orcadian Basin of northeast Scotland and is inconsistent with any Anglo-Welsh source. This relocated the search for the Altar Stone's origin to a basin roughly 700 km from Stonehenge and, by area, one of the larger sedimentary basins in Britain — stated by Clarke et al. (2026) to extend to some 10,000 km².

Bevins et al. (2024) subsequently investigated Mainland Orkney directly, applying portable XRF, automated SEM-EDS mineralogy, and clay XRD to field samples from the Stromness and Rousay Flagstone formations, and concluded these specific units do not match the Altar Stone — principally on abundant detrital K-feldspar and the near-absence of the diagenetic baryte cement and tosudite clay that characterise the Altar Stone. This is a well-evidenced exclusion of the sampled units. It is not evidence about the roughly 96–plus per cent of the basin's Devonian outcrop — across Caithness, Sutherland, the Moray Firth coast, Aberdeenshire outliers, and Shetland — that has not been sampled in the same way (the BGS Geology 625k bedrock map used in this study confirms that the great majority of preserved Old Red Sandstone outcrop lies well outside the limited, monument-adjacent ground sampled on Orkney).

This paper reports a systematic, reproducible, desk-based screen of that unsampled remainder, built entirely from free, nationally available geochemical and geological datasets, intended to rank locations for future field sampling rather than to substitute for it.

2. Data and Methods

2.1 Source records

Four records underpin the analysis.

  • Altar Stone geochemistry: Bevins, R.E., Pearce, N.J.G., Ixer, R.A., Pirrie, D., Andò, S., Hillier, S., Turner, P., Power, M. (2023). “The Stonehenge Altar Stone was probably not sourced from the Old Red Sandstone of the Anglo-Welsh Basin: Time to broaden our geographic and stratigraphic horizons?” Journal of Archaeological Science: Reports, 51, 104215. https://doi.org/10.1016/j.jasrep.2023.104215.
  • BGS G-BASE barium grid: national 500 m kriged stream-sediment grid. bgs.ac.uk/download/g-base-for-the-uk-barium_grid/ (confirmed).
  • BGS G-BASE rubidium grid: as above. bgs.ac.uk/download/g-base-for-the-uk-rubidium_grid/ (confirmed).
  • BGS Geology 625k: national bedrock, fault, and superficial-deposit polygon/line GIS layers. bgs.ac.uk/download/bgs-geology-625k-gis-line-and-polygon-data-shapefile-format/ (confirmed).

Full technical provenance, exact file names, grid parameters, and coordinate reference system details are given in Appendix A.

2.2 Geochemical threshold

Bevins et al. (2023) report that 105 of 106 in-situ pXRF analyses of the Altar Stone exceed 1025 ppm Ba, with a mean above 2750 ppm; Sr correlates with Ba (Sr = 0.0092·Ba + 91, r = 0.71). The 1025 ppm value is used as an absolute floor throughout.

2.3 Ba/Rb ratio and threshold derivation

Checking the underlying raw pXRF data supplied with Bevins et al. (2023) directly (n=56 in-situ Altar Stone analyses in the supplementary dataset; mean Ba 2758 ppm, confirming the published figure) gives a mean Ba/Rb ratio for the Altar Stone of 108.5. The same dataset gives mean Ba/Rb ratios of 48.4 for sample WM-6 (which Bevins et al. 2023 describe as matching the Altar Stone on rubidium), against 22.5 for LORS-27 and 12.5 for LSF2-5504 (both described as excluded on rubidium grounds) — an ordering fully consistent with the paper's discriminant. One nuance is worth stating precisely rather than smoothing over: checked as simple sample means, only LSF2-5504's Rb (95.9 ppm) is close to the paper's ‘~3x higher’ description relative to the Altar Stone's mean Rb (26.1 ppm); LORS-27's mean Rb (27.6 ppm) is almost identical to the Altar Stone's. The paper's comparison is most likely made at matched Ba levels rather than as unconditional sample means, which this check cannot independently reproduce from summary statistics alone.

No absolute Rb concentration for the Altar Stone is put forward in that paper as a standalone provenance criterion, and the rock-level ratios above are not directly transferable to the present study regardless: they are bulk pXRF measurements of solid rock, whereas the screen in this paper uses stream-sediment geochemistry, a physically different, diluted, catchment-averaged matrix with its own baseline. Rather than adopt an absolute rubidium cutoff imported from a different measurement matrix, a Ba/Rb ratio was calculated per grid cell from the stream-sediment grids themselves (ratio = Ba / Rb, valid cells only), with the screening threshold set at the 95th percentile of that ratio's own distribution within the chosen study extent (Section 2.6) — a threshold internal to the stream-sediment dataset, not an attempt to reproduce the Altar Stone's own rock-level ratio. This follows standard exploration-geochemistry practice of using element ratios, rather than raw concentrations, to reduce sensitivity to the ‘nugget effect’ — uneven local concentration of heavy minerals caused by hydraulic sorting in stream sediment.

The composite screening condition applied to every 500 m grid cell was therefore: Ba ≥ 1025 ppm AND (Ba/Rb) ≥ P95(ratio, within the study extent). Within the extent used here this evaluated to a ratio threshold of 13.76.

2.4 Clustering and cluster-level statistics

Cells meeting the composite condition were grouped by 8-connected connected-component labelling; clusters smaller than three cells (0.75 km²) were discarded as noise. For each surviving cluster, area, centroid coordinates, mean Ba, mean Rb, and mean ratio were recorded. Every result reported below is therefore a district-scale geochemical anomaly of 0.75 km² or larger, not a point location; the method ranks areas warranting field attention, not candidate quarry faces.

2.5 Bedrock verification

A geochemical anomaly indicates a location is of interest; it does not indicate what rock is present. Every individual grid cell within every cluster — not merely each cluster's centroid — was checked by point-in-polygon spatial join against the BGS Geology 625k bedrock layer, retrieving formation name (LEX_D), lithology description (RCS_D), and chronostratigraphic age (MAX_PERIOD/MIN_PERIOD). A cell was classified as genuine Old Red Sandstone if its age included Devonian and its lithology description did not contain any of: igneous, lava, tuff, schist, ultramafite, pyroclastic, metabreccia, felsic-rock, or gneiss — excluding Devonian-age igneous and metamorphic rock, which shares the age but is a different rock type. Each cluster's reported percentage is the proportion of its constituent cells meeting this test.

2.6 Study area

The analysis was run within an OSGB36 bounding box of easting 225,000–480,000, northing 790,000–1,219,700, covering the Moray Firth to Shetland. This is a pragmatic rather than a geologically principled boundary, and its edges produced two identifiable classification errors during development, both subsequently corrected by manual inspection (the Helmsdale/Brora Outlier locality and, more marginally, ground near Gamrie Bay and Pennan). Restricting to Great Britain as a whole would remove this edge-effect risk at the cost of also returning the already-independently-excluded Anglo-Welsh Basin outcrop; a dissolved outline of Devonian sedimentary polygons north of the Highland Boundary Fault would be a preferable extent for any future iteration of this method but was not implemented here.

2.7 Ancillary tests

Fault proximity. It was hypothesised that distance to a mapped fault could flag likely vein-hosted mineralisation (a known confound: see Section 3.4) as distinct from genuine sedimentary cementation. Distance from each cluster to the nearest BGS 625k fault line was calculated. The test did not discriminate as hypothesised: the two best-confirmed genuine Old Red Sandstone clusters (Helmsdale, 0.03 km from a mapped fault; Shetland, 1.15 km) sit closer to mapped faults than the confirmed vein locality at Yesnaby (2.46 km), because fault-bounded preservation is also the mechanism by which many Old Red Sandstone outliers survive erosion. This ancillary filter is reported as a negative result and was not incorporated into the final screen.

Superficial deposits and glacial till. The bedrock spatial join (Section 2.5) implicitly assumes stream sediment reflects the rock immediately beneath it. Checking the 31 clusters classified as 0% Old Red Sandstone against the BGS superficial deposits layer found 20 of the 31 are mapped as till-covered rather than exposed bedrock, meaning the underlying assumption does not hold for the majority of ‘excluded’ clusters. The superficial layer records deposit type only, not provenance, at this scale, so till origin could not be resolved directly. Published reconstructions of the last ice sheet's flow across this ground describe the dominant pattern as movement from the Sutherland/northwest Highlands basement northeastward onto the Caithness Old Red Sandstone lowlands, with a later phase moving northwest from the Moray Firth basin — both directions carrying material toward, not away from, the Old Red Sandstone ground, which argues against large-scale Old Red Sandstone-derived till having been transported into the basement clusters excluded here, though this cannot be confirmed at the level of any individual site without local striae or clast-lithology data not available for this study.

3. Results

3.1 Regional barium contrast

Screened on the barium floor alone, Orkney 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 mainland Caithness/Sutherland/Moray/Black Isle and 2.8% for Shetland: a roughly 350-fold contrast between Orkney and the mainland basin.

3.2 Composite Ba/Rb ratio screen

Applying the composite condition (Section 2.3) across the full study extent yielded 45 clusters of area ≥0.75 km². Bedrock verification (Section 2.5) classified these as follows:

CategoryClustersGenuine ORS area
≥50% of pixels on real Devonian sedimentary rock265.5 km²
Partial mix — real ORS present, under half the cluster639.75 km²
0% — confirmed basement, granite, or metasediment370 km²

Click to embiggen

Figure 1. Verified Ba/Rb composite clusters across the study extent, classified by proportion of each cluster's pixels confirmed as genuine Devonian sedimentary rock by point-in-polygon join against the BGS Geology 625k bedrock layer. Grid resolution 500 m; clusters ≥0.75 km² after 8-connected component filtering.

3.3 Bedrock-verified candidates

East Caithness, near Sarclet. A 42.5 km² cluster, 98.2% genuine Middle Old Red Sandstone, mean Ba 1453 ppm (maximum 1577 ppm), mean ratio 18.2, centred at 58.33°N, 3.26°W. Strachan et al. (2021) report the precise National Grid Reference of the zircon sample (RS-ORS-18-17) as ND 3470 4270, at Sarclet Harbour — approximately 9.7 km from our cluster's centroid, with the nearest cell 6.0 km away and the farthest 13.4 km away. For their own ice-flow modelling, Clarke et al. (2026) combine Sarclet and Braemore into a single named region (“Caithness”), treating that part of their analysis at a regional rather than a point scale; the present comparison uses the more precise point location for completeness. This is the same general stretch of East Caithness coast as Sarclet, not the identical outcrop, and that distinction is kept explicit throughout this section. This cluster did not register under an earlier, absolute-rubidium-threshold version of the screen; Caithness's background rubidium runs sufficiently above a Sutherland-calibrated absolute cutoff to fail that version despite a strong underlying Ba/Rb relationship, and only emerged once the ratio formulation (Section 2.3) was adopted. An independent replication of the grid-screening component (Appendix B) reproduced the same threshold, cell count, and cluster count from the same source data; see Section 3.5 and Appendix B.6 for a discrepancy in which specific cluster that replication identified as ‘Sarclet’, and why it illustrates the bedrock-verification step's necessity rather than undermining it.

Sarclet is independently documented as GCR site 17 in the JNCC Geological Conservation Review of the Old Red Sandstone of Great Britain (Barclay et al. 2005), selected for preserving one of the best-exposed Lower Devonian sections in the northern Orcadian Basin. The exposed succession there begins with the Sarclet Conglomerate Formation — poorly sorted alluvial-fan conglomerate containing clasts of granite, schist, quartzite, and basalt derived from the local Moine basement and contemporaneous Caledonian igneous activity — resting close to basement and passing upward, over a few tens of metres, into the fluvial/aeolian Sarclet Sandstone Formation, dated to the late Emsian by spore assemblage (Collins and Donovan 1977). This basal sequence is itself a poor facies match to the Altar Stone, for the same reason set out for Loch Duntelchaig in Section 4.1. Critically, however, the same coastal belt continues up-sequence, within a few kilometres at Wick, into the fine-grained, rhythmically laminated lacustrine Caithness Flagstone Group — the facies that includes the fish-bearing Achanarras-type horizons characteristic of the Orcadian Basin's Lake Orcadie system, and considerably closer in grain size and bedding style to the Altar Stone's described fine ripple-laminated sandstone than the basal conglomerate is. Diagenetic cementation, including sulphate minerals in some beds, and clay mineralogy are both reported to vary with facies and stratigraphic position across this sequence — precisely the kind of within-basin variability that sampling confined to the Stromness and Rousay Flagstone formations on Orkney (Bevins et al. 2024) would not have captured. This does not establish which specific facies underlies the geochemical anomaly reported here, which sits roughly 10 km from the GCR site itself — that requires the field verification recommended throughout this paper — but it establishes that the right facies is documented as present within the same short stretch of coast, which is not true of the Loch Duntelchaig candidate.

Strachan et al. (2021) independently describe the same succession in more detail, consistent with the account above: the Sarclet Sandstone Group has a minimum exposed thickness of c. 435 m, comprising the 70 m-thick basal Sarclet Conglomerate (rounded clasts of volcanic, metamorphic, and granitic material) succeeded by the 85 m-thick Sarclet Sandstone, both deposited by a fluvial system flowing northwest. These are overlain by the Ulbster/Riera Geo Mudstones (lacustrine) and the Ulbster/Ires Geo Sandstone (a return to fluvial conditions, dated to the Late Emsian by microspores), with the whole group passing, apparently conformably, into Middle Old Red Sandstone strata — independent literature confirmation of the Middle ORS classification this study's own bedrock spatial join returned for the same locality.

The zircon sample itself (RS-ORS-18-17, collected at Sarclet Harbour) is described by Strachan et al. (2021) as a fine-grained, moderately sorted lithic arkose with sub-angular quartz and feldspar in roughly equal proportions, muscovite flakes below 0.5 mm, a reddish colour attributed to oxide coating on grain surfaces, and accessory pyrite, zircon, and rutile. This description, compiled for the purpose of zircon separation rather than diagenetic characterisation, does not report baryte, kaolinite, or calcite cement — the three minerals that define the Altar Stone's diagnostic signature — nor does it specify whether the feldspar present is dominantly plagioclase or K-feldspar, the ratio central to the Altar Stone's own defining characteristics. Their absence from a brief petrographic note is not evidence of their absence in the rock; it means this specific point has not yet been examined for the minerals that actually matter, which remains the outstanding task regardless of how well the geochemical and geochronological signals align.

Shetland (Melby/Walls). 85% genuine Middle Old Red Sandstone, the most consistently confirmed locality across every version of this screen.

Nairn/Elgin corridor and Helmsdale. Both partial: genuine Old Red Sandstone (the Brora Outlier, in Helmsdale's case) is present but accounts for well under half of the connected geochemical anomaly, the remainder of which extends onto adjacent, non-matching ground.

Loch Duntelchaig / Great Glen. A cluster splitting almost evenly between genuine Middle Old Red Sandstone breccio-conglomerate and an adjacent Devonian-age mafic igneous intrusion — geochemically indistinguishable, bedrock-distinguishable.

3.4 Confirmed exclusions

Yesnaby (Orkney) and a locality near Tongue (North Sutherland) both register strongly on barium but are confirmed, respectively, as vein-hosted baryte mineralisation and Lewisian Complex orthogneiss — igneous basement with no relationship to Devonian sedimentation. A cluster at Kinbrace, Sutherland, resolves to an Ordovician–Silurian granite intrusion. The bulk of the remaining Sutherland interior anomaly resolves to Lewisian gneiss, Moine psammite, and Cambrian Durness Group carbonate. None of the three small, isolated, published Old Red Sandstone outliers at Tomintoul, Cabrach, and Rhynie, nor ground near Aberdeen, produced a single composite hit, despite being genuine Devonian sedimentary outcrop — attributable either to a genuine absence of the target geochemical signature or to the limited resolution of a 500 m grid against outcrops of comparable or smaller scale.

3.5 Independent convergence with detrital zircon geochronology

Clarke et al. (2026) independently tested a small number of previously-sampled Orcadian Basin localities for detrital zircon age-spectrum similarity to the Altar Stone using Kolmogorov–Smirnov statistical comparison. Sarclet returned the strongest match of any locality tested (p = 0.96), with Braemore, Kirtomy, and Portskerra also statistically compatible and the New Aberdour outlier compatible but weaker (p = 0.08). This sits within about 10 km of the cluster identified independently in Section 3.3 above — the same short stretch of East Caithness coast, not the identical point — by a method (regional stream-sediment element ratios, screened continuously across the whole basin with no dependence on pre-existing sample locations) sharing no data or assumptions with detrital zircon geochronology (the isotopic dating of zircon crystals eroded from basement source terranes hundreds of millions of years before Old Red Sandstone deposition).

Two qualifications are necessary. First, Clarke et al. (2026) are explicit that the Orcadian Basin's zircon coverage is sparse relative to its size (up to 10,000 km²); their result identifies the strongest match among available sampled localities, not a result tested against the full basin, which is the same limitation the present screen carries in reverse — continuous basin-wide coverage of geochemistry, but no capacity to test isotopic age at any location. Second, the ice-flow modelling in the same paper finds no viable direct glacial pathway from Caithness to Stonehenge: modelled ice flow from the favoured Caithness sources disperses predominantly north and east, and only specific, less-favoured sensitivity scenarios permit transport as far as Dogger Bank, still some 400 km short of Stonehenge. The paper treats this partial pathway as speculative rather than established, citing the absence of any corroborating erratic or detrital evidence at Dogger Bank itself, a multi-millennium timing gap before any subsequent human transport, and the coarse spatial and temporal resolution of the ice-flow model. A companion study (Clarke and Kirkland, 2026) found no glacial detrital zircon–apatite signature from northeast Scotland in Salisbury Plain sediments at all. Both lines of evidence support human rather than glacial transport for the Altar Stone's journey, and both are downstream of, and independent from, the zircon match itself.

4. Discussion

4.1 Formation identity is not facies identity

The Loch Duntelchaig result (3.3) demonstrates a limit intrinsic to this method that no refinement of it removes. That locality is, in part, unambiguously genuine Middle Old Red Sandstone by formation name, age, and lithology description — and is also, on the published description of its depositional setting, almost certainly the wrong facies: coarse, basin-margin breccio-conglomerate deposited as an alluvial fan against an active fault scarp, where the Altar Stone is fine-grained, ripple-laminated, and mica-rich, indicating deposition by slow water at a distance from any such scarp. A bedrock polygon records formation and age, not depositional texture. Every result in this paper should be read as identifying locations warranting facies-level (petrographic, sedimentological) assessment, not as identifying a lithological match in itself.

Sarclet illustrates the same point from the opposite direction. The specific GCR site is itself dominated by basal alluvial-fan conglomerate and fluvial/aeolian sandstone — by the logic above, likely as poor a facies match as Loch Duntelchaig at the outcrop scale of a single site description. But because the published stratigraphy documents this basal sequence passing, within the same coastal belt, into fine-grained lacustrine flagstone facies close in character to the Altar Stone, the surrounding area cannot be excluded on facies grounds the way Loch Duntelchaig can. The distinction is not that Sarclet has been shown to have the right facies where Loch Duntelchaig has the wrong one; it is that Sarclet's documented stratigraphy leaves the question open, for a cluster roughly 10 km along the same coast, in a way that is worth resolving in the field, where Loch Duntelchaig's does not.

4.2 Failed and unresolved refinements

The fault-proximity test (2.7) is reported as a negative result rather than omitted, on the view that a plausible-sounding refinement that does not survive contact with data is informative and should not be quietly dropped. The glacial till question (2.7) is reported as unresolved rather than dismissed: a majority of clusters classified as bedrock-excluded are till-covered, the available data cannot establish till provenance directly, and the directional argument offered in mitigation is a regional generalisation, not a site-specific confirmation.

4.3 Geographic scope as a stated choice

The bounding-box approach to defining the Orcadian Basin's extent (2.6) is acknowledged as the least satisfactory methodological element of this study, having produced at least one classification error (Helmsdale) during development. Any replication of this method should either use the same coordinates for direct comparability or adopt a geologically defined extent (a dissolved union of mapped Devonian sedimentary polygons) and report the change explicitly, as cluster counts and the ratio threshold itself (13.76 in this instance) are both extent-dependent.

4.4 The value of methodological independence

The convergence with Clarke et al. (2026) at Sarclet (3.5), with the two results roughly 10 km apart on the same stretch of coast, is offered as evidence worth taking seriously in proportion to the independence of the two methods, not as confirmation in itself. Two approaches sharing no input data, no statistical framework, and no common set of prior assumptions arriving within 10 km of one another, in a basin of some 10,000 km², is a stronger form of corroboration than the same method applied twice, though it remains short of the direct petrographic and sedimentological comparison that would be required to establish an actual source.

5. Conclusion

This screen, built entirely from freely available national datasets, ranks a stretch of the East Caithness coast approximately 10 km from Sarclet, and the Melby/Walls area of Shetland, pending facies-level verification, as the two highest-priority targets for field-based follow-up within the Orcadian Basin, with the Nairn/Elgin corridor and the Helmsdale area (Brora Outlier) as secondary candidates. No location discussed in this paper has been confirmed as an actual quarry site, and none of the results reported here substitute for direct petrographic, heavy-mineral, or geochronological sampling. The method's principal value is in triage: narrowing a roughly 10,000 km² basin, at negligible cost and using only public data, to a small number of specific, geologically-verified localities, one of which independently corroborates the strongest result yet published by an unrelated geochronological method.

Data and Code Availability

The composite screening code, full per-cell and per-cluster CSV output underlying Sections 3.2–3.3 and Appendix B.6, README, and licence are archived at: https://github.com/TimDaw37/Altar-Stone-Source-Screening (CC BY 4.0). Source data are public and cited in full in Section 2.1 and Appendix A.

References

Bevins, R.E., Pearce, N.J.G., Ixer, R.A., Pirrie, D., Andò, S., Hillier, S., Turner, P., Power, M. (2023). The Stonehenge Altar Stone was probably not sourced from the Old Red Sandstone of the Anglo-Welsh Basin: Time to broaden our geographic and stratigraphic horizons? Journal of Archaeological Science: Reports, 51, 104215. https://doi.org/10.1016/j.jasrep.2023.104215.

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.

Barclay, W.J., Browne, M.A.E., McMillan, A.A., Pickett, E.A., Stone, P. & Wilby, P.R. (2005). The Old Red Sandstone of Great Britain. Geological Conservation Review Series No. 31, JNCC, Peterborough.

Clarke, A.J.I. et al. (2024). A Scottish provenance for the Altar Stone of Stonehenge. Nature.

Clarke, A.J.I., Veness, R.L.J., Kirkland, C.L., Clark, C.D., Gandy, N., Emery, A. et al. (2026). From Highlands to Henge: Refining the Provenance and Transport Pathways of Stonehenge's Altar Stone. Journal of Quaternary Science, 1–8. https://doi.org/10.1002/jqs.70080

Clarke, A.J.I. and Kirkland, C.L. (2026). Detrital zircon–apatite fingerprinting challenges glacial transport of Stonehenge's megaliths. Communications Earth & Environment, 7, Article 54. https://doi.org/10.1038/s43247-025-03105-3

Strachan, R.A., Olierook, H.K.H. and Kirkland, C.L. (2021). Evidence from the U-Pb-Hf signatures of detrital zircons for a Baltican provenance for basal Old Red Sandstone successions, northern Scottish Caledonides. Journal of the Geological Society, 178, jgs2020–241. https://doi.org/10.1144/jgs2020-241

British Geological Survey. G-BASE Geochemical Baseline Survey of the Environment, UK stream sediment geochemistry grids. bgs.ac.uk

British Geological Survey. BGS Geology 625k, GIS bedrock, fault, and superficial deposit line and polygon data. bgs.ac.uk

Daw, T. (2026). Altar-Stone-Source-Screening [code and data repository]. https://github.com/TimDaw37/Altar-Stone-Source-Screening


Appendix A — Data Sources and Replication Notes

This appendix reproduces, in full, the standalone replication document prepared alongside the main analysis, so that the method in Sections 2–4 above can be independently rerun and checked.

A.1 Source records

Full citations and confirmed source URLs for all four records are as given in Section 2.1 and the References. Grid parameters for both G-BASE grids: NCOLS 1310, NROWS 2428, XLLCORNER 250, YLLCORNER 5750, CELLSIZE 500, NODATA_VALUE −9999, coordinate reference system OSGB36 / British National Grid (EPSG:27700, false easting 400000, false northing −100000, central meridian −2°, scale factor 0.9996012717), the same CRS as the BGS Geology 625k layer.

A.2 Bedrock join fields and filter

Fields used from the 625k bedrock layer: LEX_D (formation name), RCS_D (lithology description), MAX_PERIOD and MIN_PERIOD (chronostratigraphic age). A cell is classified as genuine Old Red Sandstone if age includes Devonian and RCS_D does not contain IGNEOUS, LAVA, TUFF, SCHIST, ULTRAMAFIT, PYROCLASTIC, METABRECCIA, FELSIC-ROCK, or GNEISS.

A.3 Geographic scope

Study extent: OSGB36 easting 225,000–480,000, northing 790,000–1,219,700. This is a stated methodological choice, not a geological boundary; see Section 2.6 and 4.3 for the edge-effect risk this carries and an alternative approach not yet implemented.

A.4 What this method does and does not show

  • Does not establish depositional facies (grain size, sorting, bedding style) — formation-name and age matching only (Section 4.1).
  • Does not distinguish diagenetic cement from vein-hosted mineralisation with certainty — the Ba/Rb ratio reduces but does not remove this ambiguity.
  • Does not resolve glacial till provenance at excluded localities (Section 2.7).
  • Does not establish that any candidate location was ever quarried or could physically have yielded a block the size of the Altar Stone.

This is a desk-based screening and triage method, intended to rank locations for further attention and rule out others with reasonable confidence — not a substitute for petrographic analysis, heavy-mineral work, detrital zircon geochronology, or direct field examination.


Appendix B — Independent Replication (Grok, xAI)

The following independent replication was performed by Grok (xAI), using the exact source files and method parameters set out in Appendix A, without reference to the authors' own implementation code. It is reproduced here in full as a robustness check on the core screening result.

B.1 Verification of source records

All four foundational records were checked against the live sources and the published literature. The Altar Stone pXRF signature (105/106 analyses >1025 ppm Ba; mean Ba >2750 ppm; Sr = 0.0092·Ba + 91, r = 0.71; Anglo-Welsh look-alikes at ~3× higher Rb; no absolute Rb value published) was confirmed in the source text. The supplied G-BASE ASCII grids matched the documented headers (NCOLS 1310, NROWS 2428, XLLCORNER 250, YLLCORNER 5750, CELLSIZE 500 m, NODATA −9999) and OSGB36 CRS. The supplied BGS Geology 625k shapefile set contained the required fields (LEX_D, RCS_D, MAX_PERIOD/MIN_PERIOD) with the correct CRS.

B.2 Implementation

Grid processing was executed in Python (numpy + scipy.ndimage) in an independent sandbox environment: both ASCII grids were loaded and a joint valid-cell mask created; the Ba/Rb ratio was computed on valid cells only; the analysis was clipped to the same Scotland/Orcadian Basin box specified in Appendix A.3; the 95th percentile of the ratio distribution within the box was independently calculated at 13.758, matching the value used in the main analysis to three decimal places; the composite screen (Ba ≥ 1025 ppm AND ratio ≥ P95) was applied; 8-connected component labelling was performed with clusters below 3 cells discarded; per-cluster statistics were generated; and every passing cell (approximately 3,528 rows) plus per-cluster centroids and summary statistics were exported for downstream use.

B.3 Results

The replication reproduces the core outputs of the method. The independently calculated P95 ratio threshold (13.758) matches the main analysis. 46 clusters remained after the minimum-size filter, against 45 in the main analysis — a difference attributed to normal floating-point or clipping variation and considered immaterial. The largest and highest-barium clusters occur in the East Caithness / broader Caithness Flagstone belt and in the northern part of the study box; in particular, one cluster (228 cells, mean Ba 1775 ppm, maximum 3232 ppm, mean ratio 21.7) lies in the East Caithness Middle Old Red Sandstone province, spatially consistent with the locality reported in Section 3.3 as ‘near Sarclet’ and with the geological setting discussed in Clarke et al. (2026). This hotspot was identified from the geochemical grids and the published Altar Stone signature alone, independent of the detrital zircon results in Clarke et al. (2026), which the replication treats as independent corroboration rather than an input to the screen.

B.4 Limitations of the replication

The final per-cell point-in-polygon join to the 625k bedrock layer, the Devonian sedimentary lithology filter, and the calculation of percentage genuine Old Red Sandstone per cluster could not be executed within the replication sandbox, as GIS libraries were unavailable in that environment. The exported cell- and cluster-level data were provided as a complete, ready-to-use dataset for this step in any standard GIS package, sufficient in principle to reproduce the bedrock-verified categorisation and percentages reported in Section 3.2–3.3.

B.5 Assessment

The grid-screening component of the method is judged fully reproducible, yielding hotspots matching the main analysis in style and location, including the East Caithness anomaly and a correspondingly weak signal in the limited, previously-sampled zone around the Ring of Brodgar and Stones of Stenness on Orkney. Minor differences in exact cluster footprint or cell count between the two independent implementations are expected from floating-point and boundary-clipping variation and do not affect scientific interpretation. This replication is treated as validating both the general workflow and the specific East Caithness result as a geochemically-derived lead independent of, and consistent with, the zircon evidence in Clarke et al. (2026), subject to the same caveats set out in Section 4 and Appendix A.4 above.

B.6 Editorial note: a cluster misidentification, and why it matters

Cross-checking this replication against the bedrock-verified output described in Section 3.3 identified a discrepancy worth reporting in full rather than silently correcting. The 228-cell cluster (mean Ba 1775 ppm, mean ratio 21.7) that Section B.3 above identifies as ‘the East Caithness Middle Old Red Sandstone province, spatially consistent with … near Sarclet’ is not, in fact, the same cluster verified in Section 3.3 as the genuine Sarclet hotspot. Its coordinates (58.43°N, 4.36°W) place it in North Sutherland, near Tongue, roughly 85 km from Sarclet; and when checked against the bedrock layer, it resolves to only 1.3% genuine Old Red Sandstone, dominantly Ordovician–Silurian basement. The correctly located and bedrock-confirmed East Caithness cluster is a separate, 170-cell (42.5 km²) feature at 58.33°N, 3.26°W, 98.2% genuine Middle Old Red Sandstone, with mean Ba 1453 ppm and mean ratio 18.2, sitting roughly 10.5 km from Sarclet itself — present in this replication's own cluster set but not the one selected for narrative description in Section B.3. That 10 km separation is worth stating plainly here too: this section corrects an 85 km misattribution in Section B.3, and it would be inconsistent to let this section imply pinpoint coincidence with Sarclet village that the main analysis does not itself claim (see Section 3.3).

The cause is instructive rather than a simple error. The replication's grid-screening arithmetic — the threshold, the cell count, the cluster count — is independently correct, as Section B.3 shows. What was not, and could not be, independently verified in that sandbox was which specific cluster corresponds to a real, named, geologically confirmed location, because the bedrock spatial join (Section 2.5) could not be executed without GIS libraries. In their absence, the largest and highest-barium cluster was assumed to be the significant one and matched to Sarclet by approximate regional geography rather than by confirmed coordinates or bedrock. This is the same distinction argued throughout Section 4.1: a geochemical anomaly indicates a location is of interest, not what is actually there, or, in this case, not even reliably which named place it is. The error was caught only because the per-cluster output was checked coordinate-by-coordinate against the bedrock-verified results in Section 3.3 before this paper's data-availability materials were finalised — underscoring the value of publishing full per-cluster coordinates and statistics (as both Appendix A and this replication do) rather than summary claims alone.

Tuesday, 30 June 2026

Mapping a Geochemical Fingerprint: Using Open BGS Data to Screen for the Stonehenge Altar Stone's Source

UPDATE - Please see https://www.sarsen.org/2026/07/a-multi-element-geochemical-screen.html for an updated, corrected and expanded version of the results from this investigation. This post is still relevant as to the AI input.

A note on how this post was made: the code, the geospatial analysis, and every map below were written and run by Claude, Anthropic's AI model, working directly with me in conversation. I gave the direction, supplied the published reference maps and literature, and checked the geological reasoning against them; Claude did the data engineering and the spatial analysis. I'm saying that plainly up front rather than writing "I built a map" and quietly letting an AI's work pass as mine. Consider this an exercise in learning about AI capabilities as much as about a rock.

The Altar Stone — the six-tonne sandstone megalith lying at the heart of Stonehenge — was shown in 2024 to come not from Wales, as a century of scholarship assumed, but from the Orcadian Basin of northeast Scotland. That single result reopened an old question in a new place: where, within a basin that stretches from the Moray Firth to Shetland, did this stone actually come from?

The published case against Orkney rests on careful, multi-technique laboratory work — portable XRF, automated SEM-EDS mineralogy, clay XRD — applied to a small number of hand samples. What it doesn't do is show how that local result sits against the regional geochemical backdrop. That's a job for two public databases and some code, and it's the job I set Claude to do.

The two datasets underneath everything here

Two free, OGL-licensed British Geological Survey products do all the work in this post:

  • G-BASE — the Geochemical Baseline Survey of the Environment: national 500 m kriged grids of stream-sediment element concentrations, built from roughly 110,000 samples across Great Britain. This is where the barium and rubidium numbers come from.
  • BGS Geology 625k — a full digital bedrock map of Great Britain as a polygon database, every polygon attributed with its formation name, lithology, and geological age. This is what lets a coordinate be checked against the actual mapped rock, rather than against a rectangle drawn on a screen.

Both are direct downloads, no licence negotiation, no API key. Claude parsed the G-BASE ASCII grid headers directly, then used pyproj to convert every location of interest from latitude/longitude into the grid's native OSGB36 British National Grid coordinates, which is all that's needed to index straight into the array for any point.

Round one: barium

Rather than just colouring the map by concentration, Claude built it around the Altar Stone's own published numbers: 105 of 106 in-situ pXRF analyses of the stone exceed 1025 ppm barium, with a mean above 2750 ppm. Every grid cell clearing the first threshold is rendered in flat green; cells clearing the mean, in magenta.

A note on reading the first two maps below: they use only this simple barium scheme. They don't carry the rubidium layer described next — that uses a different colour pairing further down.

 

Click maps to embiggen

The regional contrast is stark: Orkney returns a 0.03% hit rate against the Altar Stone's barium floor (one cell, at Yesnaby), against 10.8% for mainland Caithness/Moray/Black Isle and 2.8% for Shetland — roughly 350x between Orkney and the mainland basin. The one Orkney hit, at Yesnaby, is already explained in the literature as vein-infill baryte tied to base-metal mineralisation, not the diagenetic cement actually in the Altar Stone — stream sediment can't tell those apart on its own.

Round two: a ratio, not a threshold

Barium alone can't distinguish the Altar Stone's diagenetic cement from an unrelated mineral vein. Rubidium helps, in principle: in the published Anglo-Welsh Basin comparison, the high-barium look-alikes that failed to match the Altar Stone all ran roughly 3x higher in Rb; the sample that did match on barium also matched on Rb.

Rather than impose two separate absolute cutoffs — a barium floor and a fixed "low rubidium" number with no published anchor to justify it — Claude built a Ba/Rb ratio grid instead. This is standard practice in exploration geochemistry for a good reason: stream sediment is affected by the "nugget effect," where heavy minerals concentrate unevenly depending on local hydraulics, and a ratio between two elements is far more robust against that noise than either concentration taken alone. The screen used throughout the rest of this post is barium above the Altar Stone's floor and a Ba/Rb ratio in the basin's own top 5% — again a data-driven cutoff rather than an imported number, and flagged as such.

Checked against the known cases: Yesnaby's ratio (12.1) actually sits below every genuine Old Red Sandstone candidate found in this analysis — Helmsdale (15.9), the Nairn corridor (16.5), Shetland (24.8) — which the ratio threshold correctly excludes. The vein anomaly near Tongue in North Sutherland, by contrast, produces the single most extreme ratio anywhere in the basin (39.2). Ratio doesn't solve the vein-versus-cement problem outright — an extreme enough vein still clears any threshold — but it separates the borderline cases far better than a flat concentration cutoff does.


A test that didn't work, worth being honest about

One more refinement was worth trying and worth reporting even though it failed: could known fault lines be used to automatically flag likely vein contamination, on the logic that base-metal veins cluster along structural weaknesses? BGS publishes a fault-line layer at the same 1:625,000 scale as the bedrock polygons, so this was a cheap thing to check.

It doesn't work, and the reason is instructive rather than just disappointing. Helmsdale — one of the two best-confirmed genuine Old Red Sandstone hits in this whole analysis — sits 0.03 km from a mapped fault, essentially on top of one, because the Brora Outlier survives as an outlier precisely because it's a fault-bounded, down-faulted block. Shetland's Melby cluster sits 1.15 km from a fault. Yesnaby, the one site the literature explicitly documents as vein-hosted, sits 2.46 km away — further than either of the genuine hits. Fault proximity at this scale flags basin-margin sedimentary preservation just as readily as it flags vein mineralisation, and the fine structures that actually control mineralisation at a site like Yesnaby are well below what a 1:625,000 map resolves in the first place. A more detailed 1:50,000 fault layer exists and might do better, but going and fetching it felt like the wrong call: bolting a sharper-sounding filter onto a screening exercise like this risks implying a level of locational precision the underlying method doesn't actually have. Better to say plainly that this one didn't work than to quietly drop it.

Checking every candidate against the actual bedrock

A geochemical filter can flag a location as interesting. It can't tell you what rock is actually there — Sutherland alone produced hits on Lewisian gneiss, Moine psammite, Cambrian quartzite, and half a dozen granite intrusions, none of them remotely Old Red Sandstone. Getting past that requires checking each hit against the real mapped geology.

Claude loaded the BGS bedrock polygon layer with geopandas, filtered to Devonian-age sedimentary lithologies (excluding the Devonian-age igneous intrusions and lavas that share the same age but are a different rock type entirely), and ran every individual 500 m pixel of the composite mask — not just each cluster's centre point — through a spatial join against the polygons. That gives an honest number per cluster: what fraction of it actually sits on mapped Old Red Sandstone.

CategoryClustersGenuine ORS area
≥50% of pixels on real Devonian sedimentary rock265.5 km²
Partial mix — real ORS present, but under half the cluster639.75 km²
0% — confirmed basement, granite, or metasediment370 km²

Click to embiggen

The standout result is new: a 42.5 km² cluster on the East Caithness coast, near Sarclet, comes back 98% genuine Middle Old Red Sandstone — the cleanest hit in the entire analysis after Shetland. It didn't show up under a flat rubidium cutoff at all; Caithness apparently runs a little higher in background Rb than Sutherland, enough to fail a Sutherland-calibrated absolute threshold even where the underlying Ba/Rb relationship is strong. It's also worth being precise about why this particular stretch of coast is already familiar. A 2026 paper (Clarke et al., Journal of Quaternary Science) independently arrived at the same ground by a completely different route: rather than screening geochemistry across the basin, they ran statistical age-spectrum matching (Kolmogorov–Smirnov tests) on published detrital zircon data from a small number of previously-sampled localities, and found Sarclet gave the single strongest match to the Altar Stone anywhere tested — statistically indistinguishable, p = 0.96. That paper's ice-flow modelling, which made the news, is a separate step downstream of that result, used to test whether glaciers could have carried the stone south (they couldn't — flow ran east into the North Sea, not south to Wiltshire), not how Caithness was identified in the first place. The zircon match and this geochemical screen depend on none of the same data or assumptions — one dates crystals eroded out of billion-year-old granites, the other measures modern element dispersal in stream sediment — which makes two unrelated methods landing on the same 42.5 km² of coastline a genuinely useful cross-check, not a coincidence of one method run twice.

Shetland's Melby/Walls cluster holds up again at 85% genuine ORS, the most consistently confirmed site across every version of this analysis. Helmsdale and the Nairn/Elgin corridor are both real, if partial — genuine Old Red Sandstone sits inside a larger, mixed geochemical anomaly rather than accounting for all of it. A cluster near Loch Duntelchaig on the Great Glen splits almost evenly between genuine Middle ORS breccio-conglomerate and an adjacent Devonian-age mafic intrusion — the geochemistry can't tell which side of that boundary a given stream sample fell on, but the bedrock map can.

None of the three small, isolated Old Red Sandstone outliers at Tomintoul, Cabrach, and Rhynie — nor anything near Aberdeen — produced a single hit, despite being genuine, published ORS.

The glacial smear problem

There's a real weakness underneath everything above, and it's worth stating plainly rather than leaving it implicit: checking a location against the bedrock polygon assumes the stream sediment there reflects the rock directly beneath it. In heavily glaciated terrain, that assumption is often wrong. Northern Scotland was covered by ice sheets that eroded, transported, and dumped material well away from its source, and a stream cutting through a thick sheet of glacial till is sampling that till, not the solid geology underneath it. A patch of Moine basement blanketed by till that happens to contain reworked Old Red Sandstone would produce exactly the barium-and-rubidium signature this analysis is hunting for — and the bedrock spatial join, which only ever looks at what's mapped under the till, would discard it as basement regardless.

That's not a hypothetical: checking the 31 clusters this analysis classified as "0% ORS, confirmed basement" against BGS's own superficial deposits map shows that 20 of the 31 sit on mapped till, and only one sits on clearly exposed rock. "0% of pixels on ORS bedrock" and "0% chance the stream sediment there carries any ORS material" are not the same claim, and the table earlier in this post was, strictly, only entitled to make the first one.

The obvious next move — join those 20 clusters against the superficial layer and see whether the till itself is ORS-derived — turns out not to be available as a download. At this scale, BGS's superficial deposits map records deposit type (till, peat, sand and gravel) but not provenance; a polygon labelled "diamicton" carries no attribute for which rock it eroded from. Building a confident-sounding provenance model on top of a layer that doesn't actually contain provenance would be the same mistake made and abandoned with the fault-distance test earlier — a filter that sounds more precise than the underlying data can support.

What is checkable is direction. Published reconstructions of the last ice sheet's flow across this specific ground describe the dominant pattern as ice moving out of Sutherland, northeastward, onto the Old Red Sandstone lowlands of Caithness, with a later phase arriving from the Moray Firth basin, also flowing into Caithness rather than away from it. Both documented phases move material toward the ORS ground, not away from it into the Lewisian and Moine terrain to the west. That's the opposite direction from the scenario this problem raises: if till-borne contamination is happening at basin scale here, the likelier version is basement material draped over parts of Caithness, diluting a genuine signal, rather than Old Red Sandstone smeared west into the basement clusters this analysis discarded. It doesn't clear any individual site — a local reversal or a late-stage flow switch could still be sitting under any one of those 20 till-covered clusters, and confirming or ruling that out would need site-specific striae or clast-lithology data this analysis doesn't have. But it's a reason for measured rather than acute concern about the basement exclusions specifically, and if anything it means the East Caithness hit reported above is slightly more notable than it looked: a clean 98% match found despite a documented dilution risk running the other way.

Why "is it Old Red Sandstone" is the wrong-sized question

The Loch Duntelchaig result is the cleanest illustration of a limit that no amount of better data removes. That location is, in part, unambiguously genuine Middle Old Red Sandstone. It is also almost certainly the wrong rock for Stonehenge regardless, because it's coarse, basin-margin breccio-conglomerate — laid down as an alluvial fan hard against an active fault scarp — while the Altar Stone is fine-grained, ripple-laminated, mica-rich sandstone deposited by slow water nowhere near a fault scarp. Both are correctly labelled Middle Old Red Sandstone. A bedrock polygon, however precise, records the formation name, not the depositional texture.

Every filter in this post is a geochemical threshold and a formation label. That combination tells you a location is worth a second look. It doesn't tell you the rock there looks anything like the stone at Stonehenge. The next test isn't another element or a better map — it's facies: grain size, sorting, bedding style, depositional setting. That's not visible in a stream-sediment grid or a 1:625,000 polygon, and it's not something that can be finished from a desk.

What it adds up to

  • East Caithness (Sarclet area) is the strongest new lead this analysis produced — 98% confirmed, and reached independently by a 2026 detrital zircon age-matching study using none of the same data as this one.
  • Shetland (Melby/Walls) remains the most consistent candidate across every screen applied so far.
  • Helmsdale and the Nairn/Elgin corridor are real but partial — genuine ORS inside a broader, mixed anomaly.
  • Loch Duntelchaig is real ground with an explicit asterisk on facies.
  • Tomintoul, Cabrach, Rhynie, and Aberdeen — genuine ORS, geochemically silent in this dataset.
  • A fault-proximity filter sounded like a reasonable refinement and did not survive contact with the data — worth keeping in the writeup precisely because it didn't work.
  • Everywhere else that lit up — the bulk of Sutherland, the Cairngorms, upper Speyside — is basement, granite, or metasediment, confirmed against the actual bedrock map rather than assumed from a box.

None of this replaces the rock. It's a free, fast, repeatable way to rank where a portable XRF analyser should go next, and just as usefully, where it shouldn't — and where a plausible-sounding refinement should be tried, reported honestly, and dropped when it doesn't hold up. Claude built the pipeline, ran the joins, and did the geological cross-referencing behind every number in this post; I supplied the direction and the published context that made the geology checkable at all.


Data used: BGS G-BASE barium- and rubidium-in-stream-sediment grids, BGS Geology 625k bedrock polygons, and BGS 625k fault linework, © BGS/NERC, used under the Open Government Licence. Analysis, code, and maps were produced by Claude (Anthropic). This work is independent and not affiliated with or endorsed by BGS or any of the cited research groups.


Appendix:

What This Project Actually Shows About Working With an AI, Not About Rocks

I asked Claude for a raw tally of what had gone into the Altar Stone geochemistry series: how many numbers, how many datasets, how many individual checks. The answer was bigger than either of us expected, and it seemed worth a post of its own — not because the size of the number is impressive, but because of what actually made this project move fast, and what didn't.

The numbers, for the record

  • Two national stream-sediment grids at 3,180,680 cells apiece (970,377 of them over land), plus a derived ratio grid of the same size
  • 11,244 bedrock polygons, 2,741 fault-line segments, and 10,651 superficial-deposit polygons, all for the whole of Great Britain
  • Roughly 5,090 individual point-in-polygon spatial joins run against the bedrock layer — every 500 m pixel of two separate composite anomaly masks, checked one at a time, not sampled
  • Around 85 cluster-level profiles built across two screening passes, each with its own area, coordinates, element concentrations, ratio, percentage of genuine Old Red Sandstone, and dominant formation name
  • 40-odd named locations individually converted between coordinate systems over the course of the series

None of that is the interesting part. Checking whether a number clears a threshold across three million grid cells is arithmetic, not judgement, and a laptop could do it in about the time it takes to read this sentence.

What actually made this move: breadth, not depth

This project touched stream-sediment geochemistry, Quaternary glacial geology, structural geology, Devonian stratigraphy, coordinate reference systems, Python scientific computing, and cartographic design — in roughly that order, sometimes twice. A working geochemist, a GIS specialist, a Quaternary geologist, and a programmer are, ordinarily, four different people. Getting this done conventionally would mean either finding someone who is unusually all four at once, or assembling a small team and paying the coordination cost that comes with one — meetings, handoffs, someone waiting on someone else's output before they can start their piece.

Claude's competence across those six areas isn't deep in any one of them — it's not going to out-argue a structural geologist about fault kinematics, and it shouldn't. What it removes is the switching cost between them. Parsing a BGS ASCII grid header, converting coordinates with pyproj, running a connected-component clustering pass with scipy, spatial-joining against a shapefile with geopandas, and turning the result into a legible map happened back-to-back, inside single replies, with no gap for context-switching or for waiting on a different specialist's calendar. For a screening exercise like this one — not a publishable geological survey, a triage tool for deciding where to look next — that's the right shape of capability. Breadth without depth is a liability for a definitive answer and an asset for narrowing down where to look for one.

The other thing that made this move: failure was free

Refining the post at least three ideas were tried and dropped inside the same conversation they were proposed in: an unsupervised-clustering alternative to the rubidium threshold, a fault-proximity filter for vein contamination, and — almost — a full superficial-deposits provenance model that turned out not to be buildable from the data actually available. Each of those, done by a human team, would carry real sunk cost: fetching a new dataset, writing and debugging new code, probably a day or more before anyone could say whether it worked. That cost creates a quiet pressure to make an idea work once you've invested in it, which is exactly how a plausible-sounding filter survives into a final writeup even when the honest answer is "no, this doesn't discriminate anything." Here, the fault-distance test ran, failed clearly, and got written up as a failure in the same sitting — because trying it cost minutes, not days, there was nothing to protect by keeping it.

What Claude didn't do, and what that says

The genuinely load-bearing corrections in this series came from the human side of the conversation, not the AI side, and it's worth listing them rather than letting that fact hide in a disclaimer. Opening the actual BGS bedrock viewer and clicking through disputed points, catching that a box boundary happened to cut through the middle of the real Helmsdale outcrop, supplying the published stratigraphic maps that extended the search into Aberdeenshire and the Great Glen, recognising that a big dressed megalith couldn't plausibly have been quarried out of glacial till and so that particular rabbit hole wasn't worth chasing, and — the sharpest catch in the whole series* — recognising that checking bedrock polygons alone silently assumes stream sediment reflects the rock directly underneath it, which is a real and well-known problem in glaciated terrain that the analysis had been quietly ignoring for several rounds. That last one is a substantive piece of domain knowledge (drift prospecting, glacial dispersal trains) that had to be supplied, not generated.

What Claude was reliably good for was running the check once someone had the idea: is Yesnaby's rubidium actually low, yes or no; how many of the discarded clusters actually sit on mapped till, precisely; what direction did the last ice sheet actually move across this ground, according to the literature. Fast, correct execution of a well-specified question. Not, on this evidence, a reliable source of the question itself.

So what is this actually a demonstration of

Not that an AI can do a geologist's job — it can't, and nothing here should be read as suggesting fieldwork or peer review are replaceable by a chat transcript. What it demonstrates is narrower and, I think, more useful: the cost of asking one more question dropped to nearly nothing. "What if we checked this against the actual bedrock instead of a box," "what if we tried a ratio instead of a threshold," "does the till underneath change any of this" — every one of those is a legitimate research question that would normally have to be weighed against the time and effort of pursuing it, and normally most of them wouldn't get asked, because the person with the idea also has a day job and a finite number of afternoons. Here, they all got asked, most of them got answered the same day, and the ones that turned out to be dead ends got reported as dead ends instead of quietly buried. That's the actual finding of this post, and it's a smaller, more defensible claim than "AI did the research" — but it's the true one.

* This insight came from using Gemini, the Google Ai Agent, to review the work. A key takeaway is keep bouncing the work to other AI agents to check and feedback their notes into the working model, and jump to a better model if one shows up. Grok fell out of the running of this enquiry early on.


New English Heritage Reconstruction: Stonehenge Sarsens on Wooden Tracks and Rubble Ramps

A new reconstruction image of Stonehenge under construction, created for English Heritage and appearing in the book Stonehenge: The Story of an Icon by Dr Susan Greaney, shows how the 25-tonne sarsen stones may have been both transported and erected.


Infographic by The Independent/Picture Courtesy English Heritage

The illustration, based on laser-scan data and current archaeological understanding, depicts the stones being moved from the Marlborough Downs (around 15 miles away) along wooden trackways in wetland areas, and then raised into position using piles of rubble and earth rather than elaborate wooden scaffolding.

Transport: Wooden Tracks “Like a Railway”

Dr Greaney notes that previous assumptions favoured sledges running over rolling logs. The new reconstruction instead proposes static wooden trackways of laid-down timbers for sections of soft or wetland ground — preventing the sledge from sinking and allowing steady progress. She draws the comparison directly from early 20th-century photographs of megalith moving in Indonesia.

Real-world parallels still exist today. Communities on Sumba continue to drag multi-tonne stones for megalithic tombs using ropes, sledges, and organised human effort, sometimes supported by wooden infrastructure.

Upacara Tarik Batu Kubur, Anakalang, Sumba – Living Tradition
Community ritual pulling of a large megalithic tomb stone using ropes and collective effort.

Raising the Stones: Rubble Ramps and the Easter Island Parallel

Transporting the stones is only half the battle; getting a 25-tonne rock to stand perfectly upright is another. The new English Heritage visual also proposes a method for how the stones were hoisted. Rather than using complex wooden scaffolding, the builders likely used piles of rubble and earth to slowly wedge the stones upward.

“On Easter Island, it was noticed that the Rapa Nui used piles of rubble to help push the stones upright,” Dr Greaney explains. “We believe a similar method could have happened at Stonehenge.”

This comparative approach draws on ethnographic observations from Rapa Nui (Easter Island), where local people historically and in documented demonstrations used earth and rubble ramps or built-up mounds in combination with levers and ropes to raise the large moai statues.

Easter Island 1954 – Rapa Nui Demonstration of Raising Methods
Authentic 1950s footage from Thor Heyerdahl’s expedition showing Rapa Nui people demonstrating traditional quarrying, dragging, and raising techniques, including the use of levers and built-up earth/rubble.

Where to See the Full Reconstruction

The detailed reconstruction (including the wooden trackways and rubble-ramp raising method) features as a four-page fold-out in the new book:

Stonehenge: The Story of an Icon by Dr Susan Greaney (English Heritage, 2026)

Available from the English Heritage shop

Press coverage with images from the reconstruction appears in The Independent (29 June 2026).

Supporting Research

The transport element draws on comparative ethnography, particularly early 20th-century photographs from Nias Island, Indonesia, which show megaliths being moved on sledges over laid wooden tracks rather than free-rolling logs. Academic work, including Barney Harris’s 2018 paper “Moving megaliths: time to park the rollers” (Oxford Journal of Archaeology), has examined how many traditional societies used stable wooden trackways or slipways instead of the commonly imagined rollers.

The raising method proposed in the new reconstruction aligns with documented Rapa Nui practices and experimental archaeology that has tested earth/rubble ramp and lever combinations for uprighting large stones.

Monday, 29 June 2026

Brute Force and Ingenuity: The Art of Moving Megaliths by Hand

When discussing ancient megalithic construction, the debate often centres on how massive stones were moved before the invention of modern machinery. Fortunately, we do not have to rely purely on speculation. From living cultural traditions to historical footage, there are numerous documented examples of real people moving immense weights using ropes, timber, human coordination, and animal power.

Here is a curated selection of footage showing what human ingenuity and organised effort can achieve without cranes or trucks.

1. Sumba, Indonesia – Living Megalith Pulling Rituals ("Tarik Batu Kubur")

These are genuine ongoing cultural rituals in which communities drag massive megalithic stones for elite stone tombs using ropes, collective human effort, and wooden rollers or sleds. This remains one of the strongest living examples worldwide.

Upacara Tarik Batu Kubur, Anakalang Sumba Tengah
Context: Ritual pulling of a megalithic grave stone in Anakalang, Central Sumba. Clear footage of organised community effort.
Prosesi Tarik Batu Kubur (Budaya & Tradisi Orang Sumba)
Context: Full process of the traditional ceremony and stone dragging (approx. 20 minutes).
Tarik Batu Kubur Dengan Berat Puluhan Ton
Context: Emphasises the substantial weight and ritual nature of the event.

2. Toraja, Sulawesi, Indonesia – Mangriu' Batu (Stone Pulling for Noble Funerals)

In Toraja culture, hundreds of community members drag massive megaliths from quarries to ceremonial grounds to honour deceased nobles, using thick ropes, wooden sleds, and coordinated effort.

Tarik Batu: Simbol Kematian Bangsawan Toraja
Context: BBC News Indonesia footage showing the physical struggle and use of log rollers during a Toraja funeral rite.
Tradisi Menarik Batu – Kebudayaan Megalitikum Toraja
Context: Longer footage revealing the mechanics of the wooden sled/frame and rope attachments.

3. Mussolini’s Monolith, Italy (1929–1930s)

Real historical footage of a 250-tonne marble monolith being quarried in the Carrara mountains, moved down a mountainside on wooden sleds, transported by barge, taken up the River Tiber, and positioned in Rome. The operation relied on sleds, rollers, ropes, winches, and pulleys.

Moving a Monolith Old School – Ancient Technology on Display
Context: Excellent compilation of original historical footage showing the full journey from quarry to final position in Rome.
Mussolini’s Column (1929)
Context: Contemporary British Pathé newsreel showing the monolith being towed up the Tiber.

4. Northern Spain – Traditional Oxen Stone Dragging ("Arrastre de Piedra con Bueyes")

Real rural contests in Cantabria and the Basque Country where teams of oxen drag heavy stones or weighted sledges. These demonstrate traditional European draught animal power still in use today.

Arrastre de Piedra con Bueyes, Helguera de Samano
Context: Full contest footage showing oxen teams pulling large stones.
Concurso de Arrastre de Piedra con Bueyes en Liendo 2018
Context: 2018 contest recording showing the modern continuation of the tradition.

5. New England, USA – Traditional Oxen Pulling at Agricultural Fairs

In Maine and Vermont, teams of oxen compete in traditional pulling contests. Historically, oxen were widely used in North America to drag large field boulders when clearing farmland for agriculture.

Fryeburg Fair Ox Pulling (Maine)
Context: Authentic contest footage of oxen teams pulling heavy loads in a traditional New England agricultural setting.

6. Nagaland, India – Naga Tribe Stone Pulling Ceremonies

Various Naga tribes maintain a living tradition of dragging massive stones (often several tonnes) to commemorate treaties, feasts of merit, or significant events. Hundreds of participants pull the stones using thick braided vines or ropes.

Angami Naga Stone Pulling Ceremony
Context: Footage of villagers chanting and pulling a large stone during a traditional ceremony in Kigwema village.
Nagaland: Stone Pulling Ceremony – 142 Years of Anglo-Naga Peace Treaty
Context: News footage of a large-scale community effort along a modern road.
Tuophema Stone-Pulling Ceremony
Context: Recent Hornbill Festival footage showing a very large monolith being hauled by a massive crowd.

7. Easter Island (Rapa Nui), 1954 – Indigenous Demonstration

During Thor Heyerdahl’s 1954 expedition, local Rapa Nui people demonstrated how their ancestors quarried, moved, and raised multi-tonne moai using only ropes, wooden poles, and leverage.

Easter Island 1954 – Quarrying, Moving & Raising the Moai
Context: Authentic 1950s footage showing Rapa Nui participants demonstrating traditional dragging with ropes and the lever-and-fulcrum method for raising stones.

Implications for Ancient Megalith Transport

These examples from living traditions and historical records demonstrate that organised groups of people, using ropes, wooden sleds or rollers, levers, and in some cases draught animals, have successfully moved stones weighing many tonnes — sometimes over difficult terrain and for considerable distances.

While the specific challenges of the Stonehenge megaliths (their size, the distance involved, and the available archaeological evidence) remain subjects of active research and debate, the footage above shows that such movement was within the practical capabilities of pre-industrial societies when sufficient labour, social organisation, and simple technology were available.

Saturday, 27 June 2026

Morphogenesis of Cup-Shaped Depressions in Sarsen Stones

 


The entrance to the Long Barrow at All Cannings, showing natural cup shaped voids in the sarsens.

Sarsen stones (Palaeogene silcretes) are intensely indurated, composed almost entirely of quartz sand grains bound by syntaxial quartz overgrowths. Despite their extreme hardness and chemical stability, their surfaces frequently exhibit circular or sub-circular, cup-shaped depressions. Distinguishing natural geological features from anthropogenic modification (e.g. Neolithic cup marks) requires analysis of a feature's micro-morphology, formational context, and weathering history.

Why the boundaries are sharp

A sarsen boulder typically goes from fully indurated rock to friable or loose sand with little sign of a graded 90%/70%/50%-cemented halo in between — true both at a boulder's outer surface and at internal boundaries against inclusions. This is a property of how silica cementation works, not a gap in the rock record, and it underpins several of the mechanisms described below.

  1. Precipitation happens at interfaces, not through a volume. Silica tends to come out of solution where conditions change abruptly — at the water table, at permeability boundaries, where groundwaters of different chemistry mix, or across redox/pH fronts. Once supersaturation is crossed, cementation proceeds rapidly along that interface rather than diffusing evenly outward. This is documented directly in an analogous deposit: tightly cemented sandstone lenses in the Fontainebleau Sand (Oligocene, Paris Basin) sit immediately within otherwise loose, unconsolidated sand, with the sharp contrast attributed to silica precipitating along a specific hydrological interface (Thiry & Maréchal, 2001).
  2. The cement grows in discrete pulses, not a steady film. Cathodoluminescence imaging of Stonehenge sarsen Stone 58 shows the quartz cement built up as an initial thin zone followed by around sixteen separate growth generations (Nash et al., 2021) — direct evidence that cementation proceeded episodically through time. That doesn't by itself prove the boundary is spatially sharp, but it rules out "slow, steady, uniform thickening" as the model, and is consistent with a threshold-driven process.
  3. Cementation chokes off its own further spread. As a patch of sand cements, its porosity and permeability collapse, diverting silica-bearing groundwater around the cemented zone rather than through it. Ongoing precipitation concentrates at the still-open margin instead of thickening a broad halo evenly. This permeability feedback — cementation progressively sealing off the flow that feeds it — is a generic feature of reactive transport in porous media, and it sharpens fronts rather than blurring them.
  4. Most UK sarsens are groundwater silcretes, not pedogenic ones, and that distinction matters: groundwater silcretes form along specific subsurface flow paths and interfaces, favouring sharp contacts, consistent with UK sarsen's simple, structureless fabric and lack of pedogenic features such as geopetal or colloform structures. Pedogenic silcretes, which form within a soil profile through repeated wetting, drying and translocation, are generally understood to show more gradational or nodular boundaries tied to soil horizons — though I haven't found a source making that comparison explicitly for sarsen, so treat it as a reasonable extension of the general pedogenic-vs-groundwater silcrete literature rather than a confirmed point.
  5. Timing: the Palaeocene–Eocene Thermal Maximum (PETM). Several independent strands of work link UK Palaeogene silicification — sarsen and the related Hertfordshire Puddingstone — to the PETM (c. 56–55.5 Ma), when elevated temperatures and weathering rates would have raised silica mobility and favoured rapid, localised precipitation (Worsley, 2019). This is a separate question from why the boundaries are sharp, but it supports treating UK sarsen formation as a comparatively brief, climatically distinctive episode rather than slow uniform diagenesis over millions of years.

Relevance to what follows. This isn't a fifth mechanism alongside the four below — it's the underlying reason several of them produce sharp-edged features rather than blurred ones:

  • The sharp rim of a selective-dissolution void (mechanism 3) isn't created by the dissolution itself. It's inherited from the moment of cementation: the inclusion never took part in the silica cementation reaction, so the boundary between it and the surrounding cemented sand was already sharp the day the sarsen finished forming. Dissolution, much later, just empties out a void whose edge was sharp from the start.
  • Root holes and burrow traces (mechanism 1) are preserved sharply for the same reason: the cementation front "freezes" whatever was already in the sand — including an open or sediment-filled tube — at the moment it reaches that point, rather than blurring it as growth proceeds.
  • A sarsen boulder's own outer edge, where it meets the sand body it grew within, is the largest-scale expression of the same principle: a sharp boundary between sand that got drawn into the self-reinforcing cementation process, and sand just outside it that never did.

A note on terminology

"Gnamma" and "tafoni" are both sub-aerial weathering-pit terms — gnamma conventionally for granite, tafoni for sandstone — and both depend on processes that only operate at an exposed surface: rainwater ponding, lichen colonisation and the organic acids it produces, and freeze-thaw cycling. None of these operate on a stone that is buried. Applying either term to a depression that formed while a sarsen sat below ground is a category error, however similar the resulting cup-shape looks.

For the burial-context mechanism, the more accurate and lithology-neutral term is selective dissolution (sometimes "differential dissolution"): a softer or more soluble inclusion is preferentially removed from a chemically resistant host, leaving a negative cast. This is the same process documented in "omar" pits, where carbonate concretions dissolve out of Hudson Bay greywacke erratics. Reserve "gnamma" / "tafoni" for genuinely sub-aerial features; use "selective dissolution void" (or "primary void") for the burial-context equivalent.

Cup-shaped depressions in sarsens generally originate from four distinct mechanisms. The first predates the rock's induration entirely; the next two are post-lithification natural processes (one needing surface exposure, one needing burial); the last is human.

1. Primary Biogenic Structures (Root Holes & Worm Burrows)

These form within the original loose Palaeogene sand, before or during silicification — the cavity, or the trace of it, was already part of the sediment body when it hardened. This sets them apart from every other mechanism below, all of which act on the sarsen after it had already become rock.

Root holes (rhizoliths). A plant root grows down through the loose sand; when it later decays, it leaves a tubular void that becomes fossilised in place as cementation proceeds around it.

  • Typically irregular and often tapering along their length, following the natural shape of a root rather than a true cylinder.
  • May show smaller rootlets branching from a main channel.
  • Walls are often knobbly/irregular rather than smoothly bored — a plausible source of the bumpy "mammillated" texture seen on some sarsen surfaces.
  • Broadly vertical relative to the original ground surface at the time of growth, though exhumation and movement since can scramble the apparent orientation on a loose boulder.

Worm/invertebrate burrows (bioturbation). Burrowing animals active in the sand before it lithified left tunnels that are now preserved as traces — referred to formally as ichnofossils, with named genera such as Skolithos (simple vertical lined tubes) or Ophiomorpha (burrows with a distinctive knobbly, pelleted lining). Burrow ichnofossils are independently documented from the Sparnacian (basal Eocene) deposits of south-east England — the same general depositional package implicated in sarsen genesis — so they're a plausible, if not yet specifically confirmed for any individual sarsen, source for this kind of hollow.

  • More uniform in diameter along their length than a root hole — a true tube rather than a taper.
  • Orientation can be horizontal, inclined, or vertical depending on the producing organism's behaviour — less consistently vertical than root holes.
  • May show a meniscate (stacked crescent) backfill structure in longitudinal section, or a distinct lining texture (e.g. Ophiomorpha's knobbly wall) — neither of which a root hole produces.

Distinguishing this category from mechanism 3 (below): there is no "missing inclusion" to account for. The cavity, or its sediment fill, was already present in that exact form before the rock hardened around it — it isn't evidence that something solid was once there and later dissolved away. A useful field check, where a fresh break or core is available: root holes and burrows typically continue as a recognisable tube into the rock at a fairly constant diameter, whereas a selective-dissolution void (mechanism 3) is usually a single, roughly isometric cavity the size and shape of one clast, not an elongated tube.

A root hole that happens to lie at or near the exposed surface can also act as the nucleating "seed" for a sub-aerial weathering pit (mechanism 2) — the two categories aren't mutually exclusive; one can be the starting point for the other.

2. Sub-Aerial Weathering Pits (Gnammas / Tafoni)

When sarsens are exposed on the surface, horizontal or gently sloping planes can develop weathering pits.

  • Initiation: a structural "seed" — a localised pocket of incomplete silica cementation, a soft clay gall, or a root hole (see mechanism 1) — is generally required to start the pit.
  • Mechanism: once a small depression is exposed, it acts as a micro-catchment for rainwater. Standing water, combined with humic/oxalic acids from endolithic lichens and freeze-thaw wedging, attacks the syntaxial quartz cement.
  • Morphology: granular disintegration expands the pit into a bowl shape with a flared rim. The interior retains a rough, sandpaper-like texture, since dissolution removes the cement but leaves individual, un-sheared quartz grains palpable.

3. Sub-Surface Selective Dissolution (Primary Voids)

Sarsens that remained buried — in clay-with-flints, coombe rock, or other superficial deposits — are shielded from sub-aerial weathering but subject to constant sub-surface moisture.

  • Mechanism: during Palaeogene silicification, migrating silica fluids frequently bypassed or encased non-siliceous inclusions — chalk clasts, clay galls, ironstone nodules, dense organic material. Over millennia, percolating groundwater dissolves or flushes out these softer inclusions.
  • Morphology: because the surrounding silica matrix resists dissolution far more strongly than the inclusion did, the void does not expand into a bowl. It instead remains a comparatively faithful negative cast of the evacuated inclusion, with rim and interior geometry reflecting the original clast shape rather than the smooth, gravity-expanded geometry of mechanism 2.

4. Anthropogenic Modification (Cup Marks)

Human-made depressions, whether symbolic (rock art) or functional (grinding, polissoirs), can overlap in scale with natural pits — typically from a few centimetres up to around 20 cm in diameter.

  • Mechanism: created through direct mechanical force — pecking, pounding, or grinding with another stone.
  • Morphology: mechanical action fractures and shears quartz grains rather than dissolving the cement around them, producing a smoother, sometimes glazed or "bruised" interior with truncated grains — distinct from the loose, palpable grains of a dissolution feature.

Comparative summary

Root hole / worm burrow (primary biogenic)

Gnamma / tafoni (sub-aerial)

Selective dissolution void (sub-surface)

Cup mark (anthropogenic)

Formed

Before/during lithification

After lithification, exposed

After lithification, buried

After lithification, human

Context

Within original sand body

Exposed surface

Buried

Usually exposed / portable stone

Shape

Tapering tube (root) or uniform tube (burrow)

Bowl, flared rim

Negative cast of inclusion

Hemispherical, regular

Interior texture

Knobbly (root) or lined/meniscate (burrow)

Rough, loose grains

Follows original inclusion surface

Smooth, glazed/bruised, sheared grains

Diagnostic check

Tube continues at constant width into the rock; no "missing clast" to explain

Lichen/weathering nearby

Burial history; matching inclusions elsewhere in matrix

Use-wear polish; fracture signatures under microscopy

Macroscopic description can suggest a category; confirming it generally needs field microscopy or thin-section work.