Stonehenge and the Ice Age

Tuesday, 23 June 2026

Why the regional marine limit (highest shoreline) is difficult to find

I came across this fabulous oblique aerial shot the other day, of part of the coast of Svalvbard. I have labelled some of the features.

In the early days of our careers, David Sugden and I became quite good at finding the regional marine limit as we hoofed around in the landscape. We discovered one marine limit at 134m in Kjove Land, East Greenland, in 1962, and then another one at the staggering altitude of 275m at Noel Hill in the South Shetland Islands in Antarctica in 1966. The altitudes were fixed with the most primitive surveying instruments coupled with barometric checks. There were no detailed maps, and no GPS instruments in those far-off days.......

In the period since we did our fieldwork, as far as we know nobody has found higher marine traces in our fieldwork areas, or corrected our altitudes.

The marine limit in a glaciated landscape subject to isostatic adjustment or tectonic uplift is notoriously difficult to find. The reason is explained in the photo above. At the end of a glacial episode, as ice wastage speeds up and as isostatic uplift kicks in, very little of the coastline is initially subject to wave attack and other coastal processes. That is becaused of the protection afforded to the coastline by a band of landfast perennial sea ice -- sometimes called the "ice foot". It's very clear in the photo. In the deepest valleys or fjords, flowing glaciers with floating snouts effectively protect coastal solid rock outcrops, and in other embayments seasonal sea ice may also afford protection. We can see this situation at the left edge of the photo.

In the photo only one small coastal stretch is in contact with the open sea -- and this is where a range of coastal processes can operate -- just for a short time if isostatic or tectonic uplift rates are high. So on the ground today we may find washed surfaces, small pebble banks or simply till deposits from which some of the finer sediments have been removed by wave action. I recall many intense discussions with Dave while we tried to piece together the clues! And because of the relatively great age of these high beach remnants, they have of course also been modified by post-glacial slope processes and frost shattering.

In the case of the South Shetland Islands, there was reasonable evidence of a short-lived ice advance over the marine shoreline traces. It was clearly not very powerful, since the traces were well preserved. Some have suggested that the "residual raised beach" that we described may be Plio-Pleistocene in age; I disagree with that, since the remnants are so close to an ice edge that they cannot possibly have survived for that long, during multiple expansions and contractions of the King George Island ice cap or indeed the regional ice sheet cover. On the other hand, away from the areas of distinct ice streaming, island ice caps can expand to cover pereviously ice-free areas and can actually protect them. So, on balance, in my 1971 paper I suggested that the Noel Hill resudual beach may well date from the last interglacial......... Eemian or Ipswichian.

Thus far, nobody, as far as I know, has managed to date these "high level" raised marine features which David and I described in our big paper in 1971........

Saturday, 20 June 2026

Another edifice built on the sinking sands

Summer solstice madness........

Today the media are carrying the latest fantastical story about the "Stonehenge prototype" found near Bulford. The narrative is accompanied by much praise for the latest persistent and heroic archaeologist who features in video interviews -- this time not Indiana Jones or MPP, but Phil Harding

It has all been carefully planned by Wessex Archaeology, BBC and Channel 4, Time Team and English Heritage. There are excited reports all over the place, in social media and in the news outlets, about a newly discovered "structure" which showed that the locals were all very scientific and religious 500 years before the Stonehenge stone monument was thought of. Apparently a new (old) circle has been discovered, including two prominent post holes that once held huge vertical wooden posts, and lots of other holes associated with assorted finds that demonstrate the presence of an organized and busy society. In fairness to Phil Harding and the other archaeologists involved in the Bulford dig, they have not claimed that themselves, but have pointed out that the other pit traces are not on the circumference of a circle but are dotted around in several smallish groups. The artifacts discovered are not that spectacular either, if truth be told.....

But the two wooden posts deemed to have been prominent features in the landscape are apparently aligned with the midsummer solstice sunrise and the midwinter solstice sunset. So we are told by Wessex Archaeology in their press release. Apparently skyscape archaeologist Dr Fabio Silva has done the sums, and the coordinates for the 2,950 BC horizon come out exactly right. Well, not exactly, but almost......... We are not shown any calculations, so we have to take it all on trust.

There isn't any article either. We are told that there will be one somewhere, all in good time........ Neither is there a published excavation report that we can look at.

This is all completely unsatisfactory, and it is extraordinary that the media have regurgitated a Wessex Archaeology story that has not been adequately scrutinized by anybody, or even peer reviewed prior to publication.

So archaeology continues on its downwards spiral, preoccupied with banner headlines and heroic personalities -- and convinced that the media will regurgitate almost anything to do with Stonehenge, even where there is no supporting evidence at all in the public domain.

Friday, 12 June 2026

Greenland 1962: the new video

You may have noticed that the Greenland video which I posted a few days ago has now gone, to be replaced by this one. When we posted the video called "Nordvestfjord Adventure" YouTube didn't like it at all, because we were using a very obscure name that nobody ever searches for............

So we were told in no uncertain terms that we had to ditch the name and "rebrand" the video so as to be more in line with the YouTube algorithms. So here we are -- the original video with a new identity, and with a few extra editorial tweaks. Anyway, hope you like it. Please share if you wish.

Greenland 1962: into the world’s longest fjord

https://www.youtube.com/watch?v=zaF5J4KcQGw&t=25s

Greenland 1962: Into the world's longest fjord

Wednesday, 10 June 2026

Early glaciation ice rafting in the North Sea

Wroxham Crag deposits resting on chalk. Bottom left is the modern beach.

Location - Weybourne, Norfolk

This is a very interesting article that I missed in 2011 and came across in 2024:

https://brian-mountainman.blogspot.com/2024/11/ice-rafted-erratics-norfolk.html

Suddenly it seems to have considerable relevance. Sadly, the full paper still seems to be behind a paywall.

Possible ice-rafted erratics in late Early to early Middle Pleistocene shallow marine and coastal deposits in northeast Norfolk, UK.
Nigel R. Larkin, Jonathan R. Lee & E. Rodger Connell

Proc Geol Assoc 2011

https://nora.nerc.ac.uk/id/eprint/14695/1/Larkin_et_al.pdf

Abstract

Erratic clasts with a mass of up to 15 kg are described from preglacial shallow marine deposits (Wroxham Crag Formation) in northeast Norfolk. Detailed examination of their petrology has enabled them to be provenanced to northern Britain and southern Norway. Their clustered occurrence in coastal sediments in Norfolk is believed to be the product of ice-rafting from glacier incursions into the North Sea from eastern Scotland and southern Norway, and their subsequent grounding and melting within coastal areas of what is now north Norfolk. The precise timing of these restricted glaciations is difficult to determine. However, the relationship of the erratics to the biostratigraphic record and the first major expansion of ice into the North Sea suggest these events occurred during at least one glaciation between the late Early Pleistocene and early Middle Pleistocene (c. 1.1−0.6 Ma). In contrast to the late Middle (Anglian) and Late Pleistocene (Last Glacial Maximum) glaciations, where the North Sea was largely devoid of extensive marine conditions, the presence of far-travelled ice-rafted materials implies that earlier cold stage sea-levels were considerably higher.

The evidence for a high sea level is quite convincing, as is the evidence of shallow marine conditions, sea floor deposits and contained dropstones weighing up to 15 kg. The erratics are from Northern England and Norway. The stratigraphic relationships indicate that the deposits (in th Wroxham Crag Formation) date from an early glaciation maybe a million years ago. Samples came from West Runton and Sidestrand.

Preferred explanation of the occurrence of these erratics in beach and estuarine conditions: "the far-travelled clasts were deposited by melt-out from (possibly grounded) icebergs in estuarine (Sidestrand) and beach (West Runton) environments with minimal local reworking. It is predicated on parts of the BIIS and SIS in northern Britain and southern Norway having floating ice margins within the northern and eastern North Sea Basin, upstream of which ice was actively eroding and entraining bedrock lithologies. This hypothesis is supported by both the clustered spatial and stratigraphic concentration of the erratics, and their frequently comparatively ‘fresh’ form. An ice-wedge cast penetrating the host deposit at West Runton indicates that the subsequent climate was sufficiently cold to support the development of permafrost after deposition of the erratic-bearing sediments."

Conclusions

Concentrations of erratics within WCF coastal deposits at Sidestrand and West Runton in northern East Anglia are considered the product of melt-out from (possibly grounded) icebergs.

The provenance of the erratics implies that these icebergs were derived from glaciers that were eroding bedrock in the Southern Uplands, Midland Valley and southern Grampian Highlands of Scotland, and Oslofjord in southern Norway.

The age of these erratic-bearing beds can be broadly constrained to a period from the late Early Pleistocene to early Middle Pleistocene interval (c. 1.1–0.6 Ma, a time period that spans the ‘Menapian’ (MIS 34)) to late ‘Cromerian Complex’ (MIS 16) stages.

These erratics demonstrate both the existence of restricted glaciations in Scotland and Norway, and their periodic expansion into the North Sea Basin prior to the maximum extent of the ice sheets during the Anglian Glaciation (MIS 12) of the Middle Pleistocene.

This research supports the work of Sejrup et al. (1987) and Ekman (1999) that argues that both the BIIS and SIS were active in the North Sea Basin on at least one occasion well before the Anglian stage of the Middle Pleistocene.

The deposition of the erratic-bearing beds during these early glaciations appears to coincide with higher glacial sea-levels than occurred during the late Middle and Late Pleistocene.

Like the authors of the paper, I am intrigued by the glacio-isostatic and eustatic interactions here on the west side of the North Sea, where one would not expect ice rafting and the dumping of dropstones during one or more glacial episodes -- at times when relative sea levels would have been far below present msl. But here the features are, suggesting GLACIAL sea levels not far removed from those of today.................. and the authors are clear in their own minds that the features relate to marine conditions, not glacio-lacustrine conditions.

For many years there has been a widsespread belief that the North Sea Basin as a whole has been sinking tectonically while the western part of the British Isles has been slowly rising. This means that deposits currently at sea-level were deposited at an even HIGHER level around a million years ago. All very confusing.

I am checking out the current views on this paper, which was published 15 years ago.........

Tuesday, 9 June 2026

The Ixer / Bevins "lumping" con

Oh dear -- yet another piece of "dusty box" geology from the infamous bluestone duo who like to call themselves the "pet rock boys".........

We have been here before -- many times:

https://brian-mountainman.blogspot.com/2023/09/when-is-bluestone-not-bluestone.html

This 2026 item seems to be essentially the same as something previewed last year:
https://brian-mountainman.blogspot.com/2025/10/more-on-cunningtons-rock-samples-and.html

Ixer and Bevins just love digging out ancient slides made decades ago by other geologists who have been involved in Stonehenge digs, describing and classifying them and making yet more changes to their list of bluestone lithologies -- while in the process promoting their view that none of the erratic material in the Stonehenge landscape can ever have been anywhere near a glacier.

Anyway, this is the reference to the latest contribution:

William Cunnington's 1884 Stonehenge lithologies revisited
Rob A. Ixer, Richard E. Bevins, Duncan Pirrie, Matthew Power, Nick J.G. Pearce
Wiltshire Archaeological and Natural History Magazine
1 Nov 2025

Abstract

The rediscovery in 2021 of 33 thin sections of mainly Stonehenge bluestones and the re-cataloguing of their associated rock specimens has allowed for a re-evaluation/re-examination and up-dating of William Cunnington’s 1884 ground-breaking account. All the major bluestone debitage groups are represented within the thin sections (other than Rhyolite Group E from orthostat Stone 48). The thin sections include the type material for the major Andesite Group A class of debitage (from Stone 32c) and single examples for the minor groups, namely the Altar Stone, Dacite Group D and a further example of orthostat Stone 38, the type sample for Dacite Group B debitage. Spotted and unspotted dolerites and Lower Palaeozoic Sandstone from within the stones and in the wider Stonehenge Landscape are also sampled. There is a lack of any other lithologies, the only non-local, non-bluestone materials are Greensand and sarsen.

The composition of the Cunnington bluestone assemblage as seen within the thin sections and by the rock specimens is the same as those collected in the 20th and 21st centuries and this is important as it was the last to be collected from the Stonehenge Landscape before significant human disturbance/contamination of the area; hence it represents a pristine lithological base line. The plethora of exotic erratic lithologies hoped for by others is totally absent.

Several points need to be made again.

1. The obsession with "modern contamination". This is a typical straw man situation -- put something up just in order to knock it down. The assertion that "modern contamination" is a major obstacle in the way of scientific accuracy or a widely held concern among Stonehenge researchers is a highly insular viewpoint. For the vast majority of geologists and archaeologists working on Stonehenge, the landscape's modern gravel paths, car parks, and military camps were never considered a serious threat to working out the site's history. The concept of a "pristine baseline" has no value. In their re-examination of the William Cunnington archives, Ixer et al have used the phrase "pristine lithological baseline" to proactively bulletproof their own data. Because they were trying to provenance tiny flakes of debitage (rather than large, obvious standing stones), they framed Cunnington's 1880s collection as a "clean sample" to shut down any possible counter-arguments before they could be made.

2. This is all about lumping and splitting. In geology, as in other disciplines, there are lumpers and splitters. In their increasingly desperate attempts to support their human transport and monolithic quarrying hypothesis, Ixer and Bevins have systematically engaged in "lumping". Their goal has been to show that the thousands of loose debitage flakes scattered around Stonehenge match a very restricted, narrow set of parent monoliths. Obviously, if you can lump hundreds of disparate debitage fragments into just a few "coherent" groups, you can argue that they all came from a tiny number of precisely targeted human quarries. They assume, without any justification, that all of the debitage has come from destroyed monoliths. This creates an illusion of neatness and strict human selection. For example, in the Pont Saeson - Rhosyfelin area the debitage was initially deemed to contain various rhyolite subdivisions (Group A, Group B, Group C). Ixer and Bevins then engaged in a prominent lumping exercise, combining these groups under a broader category to tie them directly to a single primary source -- which was then deemed to be a Neolithic monolith quarry. They have done the same thing with the variable spotted dolerites from the Carn Goedog sill. We should never forget that (a) there is no quarry at Rhosyfelin, and (b) that there is no matching foliated rhyolite monolith at Stonehenge. There are similar problems with Group D albitised dacitic tuffs, altered gabbros, and a mixed bag of other volcanic fragments, limestones and sandstones. Multiple rock types, and therefore multiple provenances

3. On the matter of "spot provenancing" and the attempts to identify as small a number of actual monolith provenances as possible, Ixer and Bevins are essentially falsifying the record. If you look beneath the label of any single Ixer/Bevins rock type or "group," the internal petrographic and geochemical variation turns out to be massive. Within their single designated rock types, individual samples display wildly different internal fabric textures, mineral variations, altering degrees (like epidotisation or albitisation), and localized structures. If a strict, unbiased "splitting" methodology is applied to the debitage, we end up with over 40 distinct rock types rather than a tidy handful. Many of these fragments—such as the highly altered gabbros, independent dacites, and unique sandstones—still cannot be matched to any surviving standing stone at Stonehenge. Since the debitage types contain vast internal variation and include rocks that do not match the monument's orthostats, it heavily undermines the idea of clean, targeted human quarrying. Instead, it strongly implies multiple provenances. As I never tire of pointing out (somebody has to do it) this degree of variation is exactly what you would expect from a glacier entraining detritus across a diverse volcanic landscape (like the Fishguard Volcanic Group terrain) and depositing a mixed bag of gravels, cobbles, and boulders on or near Salisbury Plain. It also suggests that prehistoric builders weren't just bringing over perfectly uniform, prized pillars from two specific Welsh quarries. They were scavengers and opportunists who knew all about the minimisation of effort and cost - benefit analysis, as popinted out by Stephen Briggs. Instead, they—or the glaciers that preceded them—were gathering a highly heterogeneous collection of "exotic" rocks from many different outcrops. By lumping the rocks together, Ixer and Bevins enforce an artificial uniformity that obscures this geological variety, effectively fitting the data to support human transport while sweeping the inconveniently diverse "fingerprints" under a single taxonomic rug.

Very spotty dolerite at Carn Goedog

Very unspotty dolerite from Carn Goedog

4. The obsession with finding a "reslistically small" number of monolith provenances and quarries ignores a fundamental principle of sub-glacial geomorphology that completely upends the "quarry" narrative. Running through the work of Ixer and Bevins is a preoccupation with prominent, dramatic rock tors as the only possible source of megaliths. This is a profound misreading of how a moving ice sheet actually behaves, as I have pointed out in numerous posts. The mainstream archaeological assumption is that if a stone more or less matches a specific rock formation, it must have been physically taken off the highest, most visible cliff face available. The more prominent, the more sacred.
Glacial geomorphology shows that the opposite to be true. When a cold-based or thick ice sheet overrides a prominent rock tor, the ice is often frozen directly to the bedrock at the summit. This stagnant ice acts as a protective shield, preserving the tor's profile rather than destroying it. In contrast, the deeper, lower-lying valleys and intervening depressions between the tors experience increased pressure and friction, leading to warm-based bottom melting, plucking and entrainment. This creates a highly varied trail of erratics. This also explains why the chemical signatures of the Stonehenge debitage and the Waun Mawn stones are so untidy.

Carn Goedog -- eroded or protected by Irish Sea ice?

To conclude: They say of the Stonehenge landscape "The plethora of exotic erratic lithologies hoped for by others is totally absent." The plethora is there all right -- it's just that Ixer and his colleagues have chosen to ignore it in the context of a rather silly lumping stunt.

Monday, 8 June 2026

East coast erratics from Scandinavia and Scotland

Generalised directions of ice flow on the eastern side of Great Britain, interpreted from erratic finds and till characteristics.

Erratic finds on the east coast indicate that at various times ice from the Lake District and western Scotland flowed across the main watershed, on three main routes: via the Tweed Valley, the Tyne Gap and the Stainmore Gap. It is inferred that there was a powerful southward-flowing ice stream from Scotland very close to the current coastline.

I'm intrigued by the modelling done by Chris Clark and his colleagues for the latest paper which floats the idea of long-distance glacial transport of the Stonehenge Altar Stone.

The paper suggests that southwards transport of ORS material from the far NE of Scotland might well have been possible -- but that the "footprint" of the ice stream involved would have been rather far offshore, out in the middle of the North Sea. Probably the modelling showed ice from the Grampians and southern Scotland streaming down the east coast of England not far away from the present coastline. Further, the model might be based in part on the presence of lineations on the sea floor. We don't have a lot of detail on how the model was created.........

Anyway, one point of interest arising from this publication is the occurrence of Scandinavian and Scottish erratics in many locations on the east coast of England. More than a century ago it was believed that Scandinavian erratice were abundant -- but there was a lot of mis-labelling and mis-identifications in the early days of erratic studies, and many of the boulders vand cobbles thought to have come from Oslofjord and the south coast of Norway are now believed to have come from Stotland and even northern England.

====================

See the following:

Glaciodynamics of the central sector of the last British–Irish Ice Sheet
in Northern England
Stephen J. Livingstone, David J.A. Evans, Colm Ó Cofaigh, Bethan J. Davies, Jon W. Merritt,
David Huddart, Wishart A. Mitchell, David H. Roberts, Lynda Yorke

Earth-Science Reviews 111 (2012) 25–55

===============

Finds from till etc on the "Ice Age Coast" (Hull Geological Society):

https://hullgeolsoc.co.uk/erratics4.htm

Igneous Rocks

"Cheviot Porphyry"* (Cheviot Porpyrite of old surveys) - medium grained porphyry (smaller phenocrysts than Norwegian Porphyry) in a red, brown or black matrix. Always looks glossy as if it has been polished. Origin - ?Cheviot Hills.

Dolerite

Gabbro

Grey Granite

Larvikite - coarse grained dark rock, shines blue in sunlight when wet. May have been described as Augite-Syenite in early boulder survey publications. Origin - Larvik in Norway.

Norwegian Porphyry - yellowish phenocrysts up to 1cm in a red-brown matrix. Phenocrysts may be zoned. Origin - Oslo Fjord in Norway

Peterhead Granite - looks a bit like Shap Granite but the orthoclase phenocrysts are more of a tinned-salmon pink and not as domino shaped.

Rapakivi Granite - origin Aaland

Rhyolite - reddish-brown fine grained igneous rock. May exhibit flow banding and contain small phenocrysts. Origin - ?Cheviot Hills.

Shap Granite - pale granite containing distinctive large crystals of pale pink orthoclase (like pink dominoes), sometimes with obvious simple twinning. It is difficult to identify in small specimens because you need to see the phenocrysts, so it may be under-reported. Origin - Shap in Cumbria. There is a large boulder near the base of Sewerby Steps that can be seen when it is not covered with sand. In older publications it may be called Shap Fells Granite.

Tilberthwaite Tuff - green fine grained rock, sometimes with current bedding, fining upwards bedding and volcanic bombs. This is a volcanic ash that fell into water and was later metamorphosed (so it is an igneous, sedimentary and metamorphic rock in one!) - Origin - Lake District.

"Whin Sill" * (Whinstone of older surveys) - medium grained almost black. Origin - northern England.

Sedimentary Rocks

Black Flint - hard, black, sharp if broken, may have a white cortex. Origin - Upper Campanian and Maastrictian of the North Sea and Holderness. "Rowe Formation". May containg fossils.

Black Shelly Carboniferous Limestone - pale brown shells in a black matrix which may weather to brown. Origin - midland valley of Scotland. Matrix may be bleached or weathered to a chocolate brown colour.

Brockram - a breccia, pieces of grey limestone (usually around 25mm across) in a dull red matrix.

Brown flint - dark gey brown, hard, breaks with a conchoidal fracture, with a paler brown cotex. Probably weathered Black Flint. Not so common in Yorkshire.

Brown ripple bedded sandstone - fairly fine grained pale sandstone with ripples picked out in darker brown

Carboniferous Limestone - dark grey limestone (Mountain Limestone in older surveys)

• Coral - packed with colonial corals

• Crinoidal

• ice scratched - polished and striated; evidence of grinding with other rocks within the glacier

Striated Carboniferous Limestone cobble

Carstone - phosphatic nodules from the Aptian, occasionally steinkerns of Jurassic fossils. . Found south of the Humber.

Cementstones - large (over 30cm), grey flattened nodules, usually septarian. Origin - mostly from the North Sea or Vale of Pickering.

• Kimmeridge* - darker grey than the Speeton Clay ones

• Speeton Clay - from the B Beds

Chalk - hard, very fine grained, white. Origin - Yorkshire Wolds or North Sea (see also Soft Chalk)

Dogger* - hard orange or red fine grained ironstone from the middle Jurassic often containing fossils

Flow banded porphyritic rhyolite (Dimlington)

Frosterly Marble - dark grey to black Carboniferous Limestone with numerous large solitary corals. May be under-reported because you need ta large enough specimen to recognise it. Origin - Lower Carboniferous of Weardale.

Green Lake District conglomerate (a.k.a. "Ingleton Granite" or Greywacke Grit of old surveys) - a conglomerate with rounded clasts of quartz and other minerals up to 1 cm in size in a green matrix

Green sandstone - medium grained,

Grey Flint - from the Yorkshire Chalk. Pale or very pale grey, hard, foes not break with the conchoidal fracture you would normally "expect" for flint. Origin - Yorkshire Wolds or North Sea.

Jurassic plant bed (Esturine Sandstone of old surveys or Deltaic Sandstone) - pale grey, well bedded, mpstly quartz grains with some black plant remains.

Kimmeridge Clay - a dark grey shale often containing flattened white ammonites. Origin - Vale of Pickering or North Sea

Magnesian Limestone - quite hard, fine grained, creamy yellow colour.

Oxford Clay - grey or dark grey clay. Occasionally seen as "rafts" on the beach or in the cliff in the area around Aldborough. Origin - probably from the North Sea.

"New Red Sandstone" - medium to fine grained, with some mica, brick red colour. Origin - Permo-Trias of north west England.

"Old Red Sandstone" - medium to coarse grained, dull blood red colour. Origin - Devonian, perhaps Scotland.

Orange brown coarse sandstone - bright rusty brown colour, grains about 1-2mm, poorly cemented, may contain Tertiary foraminifera. Origin - probably from the North Sea.

Phosphate nodules - small pale brown nodules from the Speeton Clay, may contain fossils.

"Pink Chalk"* - hard, very fine grained, pink. It may not necessarily be from the "Red Chalk Formation", you would need to see distinctive fossils to be sure. Origin - North Sea and Yorkshire Wolds.

Red flint - hard, reddish brown, sharp if broken, may have a white cortex. Origin - perhaps the Danian of Denmark

Rhaxella Chert - found in Trent Valley and Norfolk, said to be from the Jurassic of the Howardian Hills (not recorded in Holderness)

Septarian nodules ( "turtle stones" ) - (see also Cement Stones)

Shelly Jurassic Limestone* - darkish grey limestone with fossils including Gryphaea, Lower Jurassic. Origin - North Yorkshire or the North Sea

Soft Chalk - white, putty-like. Can be seen in "rafts" in the cliffs. Origin - Upper Campanian and Maastrictian of the North Sea and Holderness. "Rowe Formation"

Speeton Clay - seen as "rafts" on top of the Chalk of the Flamborough area.

Red Flint - very hard, red-brown, sharp when broken, may have white cortex. Origin - perhaps the Danian of the North Sea and southern Scandinavia.

Tilberthwaite Tuff (see above under Igneous Rocks)

Metamorphic rocks -

Garnet mica schist - hard rock with sparkly muscovite and small red garnets. Occasionally you may find a version which is mostly biotite and garnets that crumbles when you try to collect it.

Gneiss

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