Constraining the Fremington Glaciolacustrine Clays:

OD-Referenced Analysis of the C.H. Brannam Ltd Borehole Survey

and its implications for the Irish Sea Ice extent.

Tim Daw tim.daw@gmail.com Sarsen.org April 2026 - Licenced under CC-BY-4.0

ABSTRACT
This report presents the first OD-referenced analysis of BGS borehole record SS53SW62–79 (BGS ID 703480), an 18-hole test boring campaign drilled by C.H. Brannam Ltd in October 1972 across the Roundswell Plain, Brynsworthy, and Claypits area of north Devon. By converting all borehole depths to metres above Ordnance Datum using corrected collar positions, the true spatial geometry of the Fremington potters clay — the glaciolacustrine unit at the heart of the formation — is established for the first time from this dataset. The analysis reveals that only 8 of the 18 boreholes confirmed the diagnostic lacustrine stratigraphy by reaching the basal glaciofluvial gravel. The remaining 10 holes, classified by Edmonds et al. (1985) as penetrating 'boulder clay', are shown to have been drilling through periglacial head and solifluction material — in three cases from collars at 41–43 m OD, some 15 metres above the lacustrine basin. These findings directly quantify a conflation first identified qualitatively by Edmonds himself in a note that was never followed to its mapping consequences. The report further demonstrates that this conflation has its root in a systematic misreading of George Maw's founding 1864 paper, which explicitly identified the overlying stony gravel as 'independent of the clay, and coeval with its erosion' — a distinction that was collapsed by Stephens (1966) and institutionalised in the BGS Sheet 293 mapping of 1982. The OD data presented here are consistent with all subsequent field observations at the Lake cutting (Hawkins & Hawkins 1990; Cattell 2003) and provide the subsurface spatial model needed to quantify the true extent of the lacustrine potters clay.

ABSTRACT

This report presents the first OD-referenced analysis of BGS borehole record SS53SW62–79 (BGS ID 703480), an 18-hole test boring campaign drilled by C.H. Brannam Ltd in October 1972 across the Roundswell Plain, Brynsworthy, and Claypits area of north Devon. By converting all borehole depths to metres above Ordnance Datum using corrected collar positions, the true spatial geometry of the Fremington potters clay — the glaciolacustrine unit at the heart of the formation — is established for the first time from this dataset. The analysis reveals that only 8 of the 18 boreholes confirmed the diagnostic lacustrine stratigraphy by reaching the basal glaciofluvial gravel. The remaining 10 holes, classified by Edmonds et al. (1985) as penetrating 'boulder clay', are shown to have been drilling through periglacial head and solifluction material — in three cases from collars at 41–43 m OD, some 15 metres above the lacustrine basin. These findings directly quantify a conflation first identified qualitatively by Edmonds himself in a note that was never followed to its mapping consequences. The report further demonstrates that this conflation has its root in a systematic misreading of George Maw's founding 1864 paper, which explicitly identified the overlying stony gravel as 'independent of the clay, and coeval with its erosion' — a distinction that was collapsed by Stephens (1966) and institutionalised in the BGS Sheet 293 mapping of 1982. The OD data presented here are consistent with all subsequent field observations at the Lake cutting (Hawkins & Hawkins 1990; Cattell 2003) and provide the subsurface spatial model needed to quantify the true extent of the lacustrine potters clay.

Borehole Map from https://api.bgs.ac.uk/sobi-scans/v1/borehole/scans/items/703466

1. Introduction

The Fremington Clay Series is a sequence of Quaternary superficial deposits on the south shore of the Taw–Torridge estuary in north Devon, approximately 4 km west of Barnstaple. The formation is notable as one of the southernmost occurrences of glacigenic or glacially-influenced sediment on the English mainland, and has been the subject of sustained scientific debate since George Maw's first description in 1864.

At the centre of the formation is a unit of smooth, stone-free, highly plastic clay — the potters clay — worked commercially for centuries and described by Maw as 'perfectly homogeneous, exceeding tough, free from the slightest grit, and as smooth and soft as butter.' This clay is the genuine lacustrine deposit: the product of quiet-water settling in a proglacial lake impounded by Irish Sea ice during a Middle Pleistocene glaciation. Above it lies a geologically distinct sequence of periglacial head and reworked stony material that is not genetically connected to the lacustrine clay below.

The distinction between these two units — clear in Maw's original paper and reinstated by field observations in the 1990 and 2003 road cutting investigations — was collapsed by Stephens (1966) and never fully reinstated in the BGS mapping of the area. As a result, the published 1:50,000 geological map (Sheet 293, 1982) maps a substantially larger area as 'Boulder Clay' than is warranted by the evidence for genuine lacustrine deposition.

This report addresses a specific and previously unexploited dataset: the 18 test boreholes drilled by C.H. Brannam Ltd (erroneously recorded as CH Brennam Ltd) in October 1972 across the Roundswell Plain, Brynsworthy, and Claypits area. The raw borehole logs, archived as BGS record SS53SW62–79, have been analysed here for the first time in terms of Ordnance Datum (OD) elevations. This conversion — straightforward in principle but not previously undertaken — reveals the three-dimensional geometry of the lacustrine basin and provides direct quantitative evidence for the extent of the head/boulder clay conflation in the BGS mapped area.

2. Background: The Two-Unit Stratigraphy and Its Misreading

2.1 What Maw Actually Described

George Maw first inspected the Fremington sections in 1852 and published his paper 'On a supposed deposit of boulder-clay in North Devon' in the Quarterly Journal of the Geological Society in 1864. His account is precise, internally consistent, and establishes a clear two-unit stratigraphic model:

The lower unit is the potters clay proper — smooth, homogeneous, stone-free, chocolate to brown, deposited in a quiet water environment and worked commercially for its exceptional plastic qualities. At the Roundswell well, sunk to the east of Fremington in 1862, Mr J. Bowden penetrated 78 feet of clay from a surface elevation of approximately 100 feet above sea level (~30.5 m OD). Of those 78 feet, the upper 12 feet was 'somewhat intermixed with stones, the number of which decreased from the surface.' The lower 66 feet was perfectly homogeneous clay — the genuine potters clay — with blackened driftwood at approximately 40 feet depth.

The upper unit is an independent stony gravel, 5 to 7 feet thick, covering the surface of the clay. On this unit Maw was unambiguous:

'This superficial gravel is, I believe, independent of the clay, and coeval with its erosion.'

This is not an incidental observation. Maw devoted specific attention to it, noting that the boulders of trap-ash in the superficial gravel 'may have been derived from the eroded clay, and left after its denudation on the surface of what remained.' He identified the stony upper 12 feet of the Roundswell well as belonging to this independent superficial gravel, 'commingled with the top of the clay at the time of its denudation.'

Maw's conclusion on the single authenticated erratic within the clay is equally important. The large boulder of basaltic trap at Combrew, found ten feet below the clay surface, is described as 'the only authenticated example of a boulder occurring in the drift.' The other boulders — those in the superficial gravel and at coastal locations — he did not regard as demonstrably part of the same deposit.

2.2 The Collapse of the Two-Unit Model

The careful two-unit model Maw established was progressively collapsed into a single 'boulder clay' through a sequence of publications that can be traced precisely.

Stephens (1966), working within a Wolstonian glacial framework, described 'a calcareous, shelly boulder clay' at Fremington and equated the entire superficial sequence from surface to bedrock with Irish Sea till. He noted a preferred pebble orientation and equated the basal gravel with the coastal raised beach deposits — a stratigraphic interpretation subsequently shown to be incorrect by Kidson and Wood (1974). Critically, Stephens did not distinguish between the upper stony head and the lower lacustrine clay; both became 'boulder clay.'

The BGS six-inch survey of Sheet 293, conducted by Edmonds and colleagues between 1968 and 1977, adopted the Stephensian framework. The resulting 1:50,000 map (published 1982) and accompanying memoir (Edmonds et al., 1985) mapped the entire superficial sequence across the valley floor as 'Boulder Clay', with the boundary between boulder clay and pebbly drift described in the memoir itself as 'arbitrary.'

The 1972 Brannam boreholes — the dataset central to this report — were drilled during the survey period and their data was available to Edmonds. He incorporated them into the memoir's discussion of the deposit, but classified the drillers' 'dirty clay' and 'overburden' as 'boulder clay', reserving 'lake clay' or 'smooth clay' only for the potters clay proper. This reclassification was not unreasonable, but led to a critical observation that Edmonds recorded and then did not follow to its mapping conclusion:

'It is noteworthy that gravel was recorded in the bottom of only those holes which penetrated smooth clays.' — Edmonds et al. (1985), Memoir for Sheets 277 and 293, p.56.

2.3 The Reinstatement of Maw's Distinction

The construction of the A39 Barnstaple Bypass in the late 1980s cut up to 9 metres through the eastern part of the deposit near Lake and provided the most extensive sections seen since the clay pits were active. Two papers from this cutting directly reinstated Maw's distinction from field observation.

Hawkins and Hawkins (1990) logged both cut faces at 20-metre intervals and produced a five-unit stratigraphy. Their uppermost unit (Unit A) — yellow-brown silty sandy clay with many angular clasts of local sandstone and mudstone — was explicitly identified as head in their own conclusion: 'the stratigraphic sequence from top to bottom [is]: head — Unit A; till — Unit B; lacustrine clay — Unit C and glaciofluvial gravel — Unit E.' They noted no evidence to support a raised beach origin for the basal gravels.

Cattell (2003), investigating a landslip in the cutting west of Lake Overbridge, went further. He recorded that the base of the lacustrine clay falls from 26 m OD at the cutting crest to 20 m OD at road level, dipping northward at 11° — the geometry of a lake basin margin. He stated explicitly that the overlying gravelly head deposit is 'typical of head deposits in the area, and not genetically connected to the underlying sequence', and placed the southern boundary of the Fremington Clay outcrop approximately 200 m south of the cutting — well north of the BGS mapped boundary.

3. The 1972 Borehole Survey: Provenance and Methodology

3.1 Survey Context

The 18-hole test boring campaign was commissioned by C.H. Brannam Ltd — the Barnstaple pottery company whose Higher Gorse Claypits were the last commercial workings in the formation — and drilled between 9 and 19 October 1972. The purpose was purely commercial: to determine whether workable reserves of stone-free potters clay existed beyond the immediate vicinity of the active pit, particularly in the Roundswell Plain and Brynsworthy areas to the east and south-east of the claypits.

The campaign was preceded by a seismic survey carried out by T.R. Wood of Bangor University around 1968 — the same Wood whose 1974 QRA field guide entry on the Fremington deposits is cited in all subsequent literature, and who is referenced in the memoir as the source of seismic data used in the BGS survey of Sheet 293. The boreholes were thus drilled into terrain whose shallow geology had already been explored geophysically.

The drilling method used a rotary-percussive hammer through overburden (which was not sampled) and switched to auger on penetrating the clay. Clay samples of approximately 24 inches in length were extracted at 2-foot intervals and bagged for Brannam's own assessment of pottery quality. Each hole was plugged with sand on completion. The maximum depth was 41 feet (12.5 m), achieved in Borehole 11.

3.2 The Original NGR Coordinates

The 1972 drilling report contains pencilled National Grid sub-grid references alongside each hole number on the log pages. These coordinates are incorrect — as confirmed by cross-referencing the BGS GeoIndex mapped borehole symbols against the location plan included in the report. The discrepancy is consistent with transcription errors in the pencilled references rather than genuine positional uncertainty. Corrected positions, derived from the BGS mapped symbol locations, are used throughout this report. All corrected positions are within the British National Grid system (OSGB36 / EPSG:27700).

3.3 The OD Conversion

No surface elevations are recorded in the original 1972 drilling report. The OD conversion was performed by cross-referencing the corrected borehole collar positions against the OS terrain model, using contour interpolation from the 1:25,000 mapping of the area. All depths in the original report are in imperial feet; conversion to metres uses the standard factor of 1 foot = 0.3048 m.

The corrected positions, surface OD values, and complete depth records for all 18 boreholes are tabulated in Section 4.

4. Borehole Register

Table 1 presents the full register of all 18 boreholes with corrected positions, surface OD elevations, and depth data from the original 1972 drilling report. Imperial depths are shown alongside metric conversions. The 'Max?' column indicates whether the borehole was terminated within clay (the log notes 'continues below' the final depth recorded), meaning the clay thickness figure is a minimum.

BH	BGS Ref	Easting (BNG)	Northing (BNG)	Surface OD (m)	O/B (ft)	Clay top (ft)	Clay thick (ft)	Max?	Gravel	Water	Clay quality
1	SS53SW62	253410	131580	25.80	20	NIL	—	N	no	no	No clay
2	SS53SW63	253460	131520	37.60	25	25	8	Y	no	no	Dirty
3	SS53SW64	253540	131600	35.10	13	13	14	Y	no	no	Dirty, worsens below 21ft
4	SS53SW65	253490	131700	32.80	11	11	19	Y	no	YES	Dirty
5	SS53SW66	253490	131880	27.66	16	16	16	Y	no	YES	Dirty
6	SS53SW67	253490	132000	24.00	13	13	12	N	YES	no	Dirty then gravel
7	SS53SW68	253740	131620	35.20	13	13	12	Y	no	no	Dirty
8	SS53SW69	254030	131620	34.70	11	11	18	Y	no	YES	Dirty
9	SS53SW70	253980	131360	41.20	9	9	20	Y	no	YES	Very dirty/earthy
10	SS53SW71	254050	131310	42.50	9	9	16	Y	no	no	Dirty/earthy
11	SS53SW72	254150	131250	42.80	9	9	32	Y	no	no	Dirty to 29ft; clean clay at 40ft
12	SS53SW73	252960	131490	36.50	12	12	18	N	YES	no	Earthy
13	SS53SW74	252950	131530	35.20	9	9	20	N	YES	YES	Good with finey
14	SS53SW75	252900	131520	35.10	9	11	14	N	YES	no	Good from 13ft
15	SS53SW76	252840	131610	31.60	9	15	10	N	YES	no	Mainly clean
16	SS53SW77	252830	131520	35.00	9	11	12	N	YES	no	Sandy/short
17	SS53SW78	253020	131920	25.20	11	11	20	N	YES	no	Good
18	SS53SW79	252990	131920	24.70	7	7	24	N	YES	no	Good; horseflesh at 17ft

Table 1. Full borehole register. Green rows = gravel reached (lacustrine stratigraphy confirmed). Red rows = surface OD >38m (above lacustrine basin). Grey row = no clay found. O/B = overburden. Max? = whether borehole terminated in clay.

5. OD-Referenced Analysis

5.1 The Gravel-Bearing Holes: Lacustrine Stratigraphy Confirmed

Eight of the 18 boreholes reached the basal glaciofluvial gravel: Boreholes 6, 12, 13, 14, 15, 16, 17, and 18. These are the only holes that confirmed the diagnostic three-tier stratigraphy of the formation: potters clay resting on glaciofluvial gravel resting on bedrock. Their OD elevations are presented in Table 2.

BH	BGS Ref	Surface OD (m)	Clay top OD (m)	Clay base OD (m)	Gravel top OD (m)	Clay thick (m)	Quality / Notes
6	SS53SW67	24.00	20.04	16.38	16.38	3.66	Gravel at 25ft. Almost no water. Only ~9ft usable.
12	SS53SW73	36.50	32.84	27.36	27.36	5.49	Earthy short clay. Gravel at 30ft. Nearly usable.
13	SS53SW74	35.20	32.46	26.36	26.36	6.10	Good clay with sand layers. Gravel and water at 27ft.
14	SS53SW75	35.10	31.75	27.48	27.48	4.27	Dirty at 11ft; good clay from 13ft. Gravel ~23ft.
15	SS53SW76	31.60	27.03	23.98	23.98	3.05	Clean clay 17–27ft. ~10ft usable. Gravel at 27ft.
16	SS53SW77	35.00	31.65	27.99	27.99	3.66	Sandy clay below 15ft. Gravel touched at 21ft.
17	SS53SW78	25.20	21.85	15.75	15.75	6.10	Good clay 11–31ft. Gravel at 31ft. Recommended.
18	SS53SW79	24.70	22.57	15.25	15.25	7.32	Best hole. Good clay 7–31ft. Gravel at 31ft. Recommended.

Table 2. Gravel-bearing boreholes with full OD stratigraphy. Gravel top OD = base of potters clay / top of glaciofluvial outwash.

The gravel top OD values — the base of the potters clay — range from 15.3 m OD (BH18) to 28.0 m OD (BH16), with a mean of approximately 21 m OD. This is consistent with the Lake cutting data from Cattell (2003), who recorded the clay–gravel contact at 19.9 and 20.4 m OD to the north of the A39, and at 20–26 m OD in the cutting itself (the higher figure representing the dipping southern margin). The agreement across two independent datasets, separated by approximately 1 km and derived from completely different investigation methods, is strong confirmation that these holes are sampling the same lacustrine basin floor.

Boreholes 17 and 18 — in Hollands land north of the old pit workings — show the lowest gravel OD values (15.3 and 15.8 m OD) and the thickest good-quality clay (6.1 and 7.3 m respectively). These are the deepest parts of the lacustrine basin reached by this survey and were correctly identified in the 1972 narrative as the best commercial prospects. Their clay top OD values (21.9 and 22.6 m OD) represent the lake floor level most closely.

Boreholes 12–16 show clay tops at 27.0–32.8 m OD and gravel at 24.0–28.0 m OD. These elevated values — compared to BH17 and BH18 — indicate that these holes are on the southern basin margin, where the deposit shallows toward the Carboniferous shale bedrock ridge to the south. Borehole 12 in particular (clay top 32.8 m OD) may be on the outermost southern rim of the basin.

5.2 The High-Elevation Holes: Above the Lacustrine Basin

Boreholes 9, 10, and 11 — located in the Roundswell–Brynsworthy area to the south-east of the claypits — show surface elevations of 41.2, 42.5, and 42.8 m OD respectively. Their clay tops, calculated from the depth records, are at 38.5, 39.8, and 40.1 m OD. Table 3 presents their OD data alongside the expected lacustrine range.

BH	Surface OD (m)	Clay top OD (m)	Expected lacustrine clay top (~20–27 m OD)	Elevation above expected range (m)	Interpretation
9	41.20	38.46	20–27 m OD	~12–18 m ABOVE	Head/solifluction. Not lacustrine clay.
10	42.50	39.76	20–27 m OD	~13–20 m ABOVE	Head/solifluction. Not lacustrine clay.
11	42.80	40.06	20–27 m OD	~13–20 m ABOVE	Head/solifluction dominant. 0.3 m clean clay only at 30.3 m OD (borehole base).

Table 3. High-elevation non-gravel boreholes. Clay tops are 12–20 m above the expected lacustrine clay level.

The significance of these figures cannot be overstated. The clay top in Boreholes 9, 10, and 11 sits at 38–40 m OD. The lacustrine potters clay surface confirmed by the gravel-bearing holes and by the Lake cutting data lies at approximately 20–27 m OD. The material encountered in Boreholes 9–11 begins approximately 15 metres above the lacustrine basin. It is periglacial head and solifluction: locally-derived stony silty clay produced by frost action and downslope movement during Pleistocene cold stages, not glaciolacustrine sediment.

This is precisely what the drillers themselves observed. Their log notes for these holes describe material that is 'very dirty and earthy', 'shorter and more earthy than the others', and — for Borehole 9 — 'this seemed dirtier and more earthy and sandy than the others... very wet throughout.' These are the sensory characteristics of solifluction head, not of the smooth, homogeneous potters clay.

Borehole 11, the deepest hole at 41 feet (12.5 m), is the most instructive case. Drilled specifically to test whether clean potters clay existed in the Roundswell area, it encountered dirty clay from 9 feet downward, with clean clay only appearing at 40 feet — in the final foot before the borehole was terminated. That 1-foot (0.3 m) horizon of clean clay, at 30.3 m OD, is approaching the upper range of the expected lacustrine basin but still above the confirmed gravel-bearing levels. The borehole was stopped before reaching the diagnostic base; the clean clay at the base of BH11 may represent the first appearance of the lacustrine unit, but this was not confirmed.

5.3 The Intermediate Holes: Head Masking the Basin

The remaining non-gravel holes — Boreholes 2, 3, 4, 5, 7, and 8 — show surface ODs of 27.7–37.6 m and clay tops at 22.8–31.4 m OD. These are less clear-cut than Boreholes 9–11, and several fall within or close to the upper range of the expected lacustrine clay zone. However, without the diagnostic basal gravel, the lacustrine stratigraphy cannot be confirmed in any of them.

The clay quality descriptions for all six of these holes are consistently negative: 'dirty', 'worsens with depth', 'very dirty and earthy'. None produced clay considered commercially usable by Brannam's. This is consistent with the interpretation that these holes are penetrating the thick head sequence overlying the lacustrine basin, without reaching the potters clay below — or are on the margins of the basin where head is thick and the lacustrine unit thin.

Borehole 1 — surface OD 25.8 m, no clay in 20 feet — was drilled in the central part of the survey area, approximately 460 m east-southeast of the Higher Gorse claypits. Its position at 25.8 m OD and failure to find clay suggest it may sit on a bedrock high or at the edge of a gap in the lacustrine deposit within the basin, rather than at the outer western margin.

5.4 Comparison with Published OD Datums

Table 4 compiles all confirmed Potter’s Clay top OD values from every independent source: the 1972 Brannam boreholes, the Lake cutting investigations, Maw’s Roundswell well datum, and the additional A39 bypass borehole 703458. Only boreholes and sections where the lacustrine clay was positively identified are included; the non-gravel holes (BH2–5, 7–11) and the 12 head-dominated additional boreholes are excluded, as they did not confirm the diagnostic lacustrine stratigraphy.

Source	Location	Position	Potter’s Clay Top OD (m)	Notes
*Basin floor: Potter’s Clay top ~20–23 m OD*
Cattell (2003)	Lake cutting — N of road	Basin floor	~20–21	Flat basin floor north of A39.
This survey — BH17	Hollands land, N of old pits	Basin floor	21.85	Best commercial hole. Gravel at 15.75 m OD.
This survey — BH18	Hollands land, N of old pits	Basin floor	22.57	Best hole overall. Gravel at 15.25 m OD.
Additional BHs — 703458	~253950, 132050 (A39 bypass)	Basin floor	~20.76	3.05 m Fremington Clay. Labelled by driller.
*Basin margin: Potter’s Clay top ~26–33 m OD*
Maw (1864)	Roundswell well (~1 km SE)	Basin margin	~26.8	Clean clay top below 12 ft stony reworked material.
Cattell (2003)	Lake cutting — S crest	Basin margin	~26	Dipping S margin; 11° N dip. Southern limit ~200 m S.
H & H (1990)	Lake cutting Ch.11000	Basin margin	~27–29	Unit C (lacustrine) top, below head (A) and till (B).
This survey — BH15	Nr Higher Gorse	Basin margin	27.03	Clean clay 17–27 ft. Gravel at 23.98 m OD.
This survey — BH6	Nr Higher Gorse	Basin margin	20.04	Gravel at 16.38 m OD. Transitional to floor.
This survey — BH16	Nr Brynsworthy	Basin margin	31.65	Sandy clay. Gravel at 27.99 m OD.
This survey — BH14	Nr Brynsworthy	Basin margin	31.75	Good clay from 13 ft. Gravel at 27.48 m OD.
This survey — BH13	Nr Brynsworthy	Basin margin	32.46	Good clay with sand layers. Gravel at 26.36 m OD.
This survey — BH12	Nr Higher Gorse	Outermost rim	32.84	Earthy clay. Gravel at 27.36 m OD. Southern limit.

Table 4. Confirmed Potter’s Clay top OD from all independent sources, grouped by basin position.

The pattern across all sources is consistent. On the basin floor, the Potter’s Clay top clusters tightly between ~20 and 23 m OD — the level at which the lake sediment accumulated. On the basin margins, the clay top rises to ~26–29 m OD as the deposit thins and laps onto the bedrock slopes, with the outermost rim (BH12) at 32.8 m OD. The convergence of the margin values from four independent datasets — Maw’s Roundswell well (~26.8 m), Cattell’s Lake cutting southern crest (~26 m), Hawkins and Hawkins’s Unit C top (~27–29 m), and the 1972 boreholes BH12–16 (~27–33 m) — implies a maximum lake surface at approximately 27–29 m OD. This is the level of the ice-dammed proglacial lake in which the Potter’s Clay was deposited: above this elevation, no lacustrine clay exists, and all fine-grained superficial material is periglacial head.

5.5 Corroborating Evidence from Additional Area Boreholes

Figure 2: BGS map of Fremington Area showing “Till” in light blues and borehole locations.

The spatial pattern established by the 1972 Brannam survey is strongly corroborated by a representative sample of 13 additional boreholes from the wider area, drawn from BGS archival records including A39 Barnstaple Bypass site investigations and other geotechnical surveys. These holes, summarised in Table 5a, span the terrain from the bypass corridor in the east (~255 317) through Roundswell (~253 305) to the western approaches (~248 314), and provide independent control on the distribution of the potter’s clay outside the 1972 survey footprint.

Of the 13 boreholes examined, 12 are dominated entirely by head deposits: stony, mottled, gravelly clay sitting directly over gravel or bedrock, with no trace of the diagnostic stone-free lacustrine clay. Their descriptions — firm to stiff yellow-brown or red-brown sandy silty clay with much subangular gravel, occasional cobbles, and variable sand content — are characteristic of periglacial solifluction head derived from local Carboniferous and Devonian sources. None records the smooth, homogeneous, stone-free clay that defines the potter’s clay proper.

The single exception is borehole 703458 (SS53SW54), located at ~253950, 132050 — centrally within the basin area at a surface OD of 22.7 m. This hole, drilled as part of the A39 Barnstaple Bypass investigation in August–September 1982 by Norwest Holst for the Department of Transport, records a substantive sequence of firm to stiff red-brown slightly silty clay from 1.95 m to 5.0 m depth (20.76–17.71 m OD), explicitly labelled “(FREMINGTON CLAY)” by the driller. This 3.05 m unit is underlain by a 0.2 m basal transition (firm to stiff brown slightly sandy silty clay with yellow-brown silty sand laminations and occasional sub-rounded gravel), then by soft brown and greenish grey sandy clayey silt with much grey subangular gravel, resting on probable siltstone bedrock at 7.5 m depth (15.21 m OD). The clay top OD of ~20.76 m and the presence of a relatively stone-free, cohesive lacustrine clay sequence are fully consistent with the basin-floor geometry established by the 1972 gravel-bearing boreholes (BH17 clay top 21.85 m OD; BH18 clay top 22.57 m OD) and by Cattell’s (2003) Lake cutting data (~20–21 m OD on the basin floor).

The pattern from these additional holes reinforces the central conclusion of the OD analysis: genuine lacustrine potter’s clay is confined to the low-elevation basin floor, and the great majority of the surrounding terrain mapped as Boulder Clay on Sheet 293 contains only periglacial head. The commercial behaviour of C.H. Brannam Ltd is instructive here. Brannam’s applied what might be called Sutton’s Law — they looked where the clay was most likely to be. Guided by T.R. Wood’s seismic survey and by generations of direct working knowledge, they targeted their 1972 boreholes on the low-elevation ground around the existing pits. They did not bore in the ground mapped as Fremington Clay south of the Hele–Bickington ridge. A pottery firm whose livelihood depended on finding workable clay, guided by geophysical survey, would not have overlooked accessible reserves if they existed. Their silence on the southern ground — Sutton’s Law applied in reverse — is itself evidence that the mapped Fremington Clay extent in that area reflects head and reworked boulder clay rather than the genuine lacustrine deposit.

6. The Edmonds Observation and the Misreading of Maw

Edmonds’ observation in the 1985 memoir — that gravel was found only in holes that penetrated smooth clay — correctly identified the diagnostic criterion for lacustrine stratigraphy. The OD analysis presented in this report quantifies its implications: the 10 holes without gravel have clay tops at 22.8–40.1 m OD, significantly above the 20–27 m OD range confirmed by the 8 gravel-bearing holes and by the Lake cutting data. In the three highest-elevation cases (BH9–11), the clay tops are 12–15 m above the lacustrine range. These holes were drilling through periglacial head throughout. The mapping of all 18 holes as ‘Boulder Clay’ on Sheet 293 followed the Stephensian framework rather than the stratigraphic logic of Edmonds’ own borehole evidence.

6.1 The Stepwise Conflation

The path from Maw's careful description to the BGS's consolidated 'Boulder Clay' can be traced through five steps:

Step 1: Taylor (1956) grouped 'Saunton and Fremington erratics' together, conflating coastal boulders of sea-ice origin with clay-embedded clasts of different transport history. This inflated the apparent exotic component of the inland deposit and gave the impression of a more extensively glaciated area than the evidence warranted.

Step 2: Stephens (1966) adopted the full glacial till interpretation, treating the entire surface-to-bedrock sequence as a single boulder clay of Wolstonian age, without distinguishing the upper head from the lower lacustrine clay. This paper became the standard reference for age and character of the deposit.

Step 3: Edmonds et al. (1985) surveyed Sheet 293 within the Stephensian framework, drew an admitted arbitrary boundary between boulder clay and pebbly drift, and mapped the full valley floor superficial as Boulder Clay. The 1972 borehole data, which contained the diagnostic information to restrict the mapped extent, was incorporated without the OD conversion that would have made its implications apparent.

Step 4: Croot et al. (1996), working at the type section in the old clay pits, focused on the lacustrine unit proper and confirmed its glaciolacustrine character with excellent sedimentological and geotechnical data. Their work is authoritative for the lacustrine unit but does not address the question of how much of the BGS mapped area represents genuine lacustrine clay rather than overlying head.

Step 5: Bennett et al. (2024), the current authoritative synthesis, accepted the BGS mapped extent as the starting distribution for the deposit. The Hawkins & Hawkins (1990) and Cattell (2003) findings — which directly reinstated Maw's distinction at the field observation level — were not connected back to the subsurface data or the mapped boundary.

6.2 What the OD Data Restore

The OD analysis presented in this report closes the loop that Edmonds opened in 1985. By establishing that the gravel-bearing holes cluster consistently around a potters clay base of 15–28 m OD — consistent with all independent published datums — and that the non-gravel holes at 38–40 m OD are clearly above the lacustrine basin, it provides the quantitative foundation for a revised mapped extent.

The true spatial boundary of the lacustrine potters clay is not coextensive with the BGS Boulder Clay polygon. It is confined to the area where the three-tier stratigraphy (potters clay on glaciofluvial gravel on bedrock) can be confirmed, which from the 1972 borehole data is limited to the vicinity of the Higher Gorse claypits and the Hollands land area to their north. The apparent extent of the deposit on Sheet 293 reflects the distribution of all fine-grained superficial material in the valley — lacustrine, head, and reworked — mapped as a single undifferentiated unit within a glacial interpretive framework that Maw himself never endorsed.

7. Summary: OD Classification of All 18 Boreholes

Table 5 presents the complete OD classification of all 18 boreholes, with each hole's status relative to the lacustrine basin and its implications for the BGS mapping.

BH	Surface OD (m)	Clay top OD (m)	Gravel OD (m)	Status	BGS Sheet 293 mapping implication
1	25.8	NIL	—	Outside basin	Boulder Clay mapping DOUBTFUL — no clay
2	37.6	30.0	—	Partial — base unknown	Boulder Clay mapping UNCERTAIN
3	35.1	31.1	—	Elevated margin	Boulder Clay mapping UNCERTAIN
4	32.8	29.4	—	Partial — base unknown	Boulder Clay mapping UNCERTAIN
5	27.7	22.8	—	Partial — base unknown	Boulder Clay mapping UNCERTAIN
6	24.0	20.0	16.4	Lacustrine confirmed	Boulder Clay mapping VALID
7	35.2	31.2	—	Elevated margin	Boulder Clay mapping UNCERTAIN
8	34.7	31.3	—	Elevated margin	Boulder Clay mapping UNCERTAIN
9	41.2	38.5	—	Head — above basin	Boulder Clay mapping INVALID — head only
10	42.5	39.8	—	Head — above basin	Boulder Clay mapping INVALID — head only
11	42.8	40.1	—	Head — above basin	Boulder Clay mapping INVALID — head only
12	36.5	32.8	27.4	Lacustrine confirmed	Boulder Clay mapping VALID
13	35.2	32.5	26.4	Lacustrine confirmed	Boulder Clay mapping VALID
14	35.1	31.7	27.5	Lacustrine confirmed	Boulder Clay mapping VALID
15	31.6	27.0	24.0	Lacustrine confirmed	Boulder Clay mapping VALID
16	35.0	31.6	28.0	Lacustrine confirmed	Boulder Clay mapping VALID
17	25.2	21.8	15.8	Lacustrine confirmed	Boulder Clay mapping VALID
18	24.7	22.6	15.3	Lacustrine confirmed	Boulder Clay mapping VALID

Table 5. OD classification summary. Green = confirmed lacustrine. Red = head above basin. Amber = elevated margin or uncertain. Grey = outside basin.

8. Conclusions

The following conclusions are drawn from the OD-referenced analysis of the 18 Brannam boreholes (BGS SS53SW62–79, 1972):

(1) The lacustrine potters clay — Maw's original deposit — is confirmed in 8 of 18 boreholes by the presence of the diagnostic basal glaciofluvial gravel. The gravel top OD in these holes ranges from 15.3 to 28.0 m OD, consistent with a basin floor at approximately 20–22 m OD and a basin margin rising to approximately 28 m OD. This is fully consistent with Cattell's (2003) Lake cutting data (gravel top 19.9–26 m OD) and with Maw's (1864) Roundswell well datum (~26.8 m OD for the clean clay top).

(2) Three boreholes (BH9, BH10, BH11) have collars at 41.2–42.8 m OD, with clay tops at 38.5–40.1 m OD — 12 to 20 metres above the lacustrine basin. The material encountered in these holes is periglacial head and solifluction, not potters clay. Their classification by Edmonds et al. (1985) as 'boulder clay' extended the mapped extent of the formation into terrain that contains no lacustrine sediment.

(3) The remaining 7 non-gravel holes (BH2–8) show clay tops at 22.8–31.4 m OD. Without the diagnostic basal gravel, the presence of lacustrine clay cannot be confirmed in any of these holes. The uniformly poor clay quality (dirty, earthy, contaminated) is more consistent with periglacial head overlying the lacustrine unit than with the lacustrine unit itself.

(4) The true spatial extent of the Fremington lacustrine potters clay is confined to the area where the three-tier stratigraphy can be confirmed. From the 1972 borehole data, this is centred on the Higher Gorse claypits area and the Hollands land to the north (the area recommended by Brannam's for commercial expansion), with the basin margins rising steeply to the south (BH12–16) and south-east (BH9–11, Roundswell area). The BGS Sheet 293 Boulder Clay polygon substantially overstates this extent.

9. Recommendations for Further Work

The OD-referenced analysis presented here provides the quantitative subsurface framework needed to revise the mapped extent of the true glaciolacustrine potter’s clay. The following targeted steps are recommended to complete the rigorous geological map and fully resolve the head-mixing issue identified in the literature:

Further borehole analysis A representative sample of the additional archival borehole records from the Barnstaple Bypass (A39) construction and associated site investigations has now been analysed and incorporated into this report (Section 5.5). The results confirm the spatial model established by the 1972 Brannam dataset: genuine lacustrine potter’s clay is confined to the low-elevation basin, with head dominant elsewhere. The remaining unsampled archival records could be OD-referenced for completeness, but given the consistency of the pattern already established across multiple independent datasets, they are unlikely to alter the conclusions materially. Priority should instead be given to the corrected map and cross-sections (below) and to targeted investigation of the ground south of the Hele–Bickington ridge.
Preparation of a corrected map and cross-sections Using the validated 1972 dataset together with the new borehole control, a revised geological map should be produced that separates the confirmed lacustrine potter’s clay (stoneless, gravel-based, low-elevation basin fill) from the overlying periglacial head. Cross-sections (e.g., Lake–Roundswell–Bickington and north–south transects across the Hele–Bickington ridge) will illustrate the true geometry of the glacial clays, the northward 11° basin-margin dip, and the extent of head overprinting. These outputs will form the core of the final project map.
Investigation of the area south of the Hele–Bickington ridge The ground mapped as Fremington Clay south of the Hele–Bickington ridge (currently included in the BGS Sheet 293 Boulder Clay polygon) should be prioritised for targeted field inspection and shallow boreholes. On the balance of probabilities this area represents reworked fluvial boulder clay or head derived from local Carboniferous sources rather than the glaciolacustrine potter’s clay. This interpretation is supported by the negative evidence from the additional area boreholes (Section 5.5), none of which found lacustrine clay south of the ridge, and by the Sutton’s Law argument set out there: Brannam’s, guided by seismic survey, showed no interest in this ground as a source of workable clay. Confirmation here will further contract the true glacial-clay extent and eliminate the unhelpful expansion introduced by later mapping.
Implications for understanding of glacial intrusion into the area This reinterpretation severely limits the inferred onshore reach of Irish Sea ice during the relevant Pleistocene stage (Anglian/MIS 12 favoured). The potter’s clay is now shown to be confined to a low-elevation (~15–28 m OD) proglacial lake basin rather than a widespread till sheet. The dominant head overprint and absence of thick, stony till across much of the mapped area indicate only marginal ice-dammed ponding in the Taw estuary, not deep glacial overriding of the Devon landscape. Preliminary thoughts suggest the ice front was pinned against the Bristol Channel coast, with the lake forming in the lee of the ice dam; this model is consistent with sparse/local erratics and the lack of far-travelled Irish Sea indicators in the clean lacustrine facies.
Implications for deeper glacial intrusion onto land The revised extent and elevation data constrain any model of deeper glacial intrusion onto land and, by extension, the viability of long-distance glacial rafting or transport of distant erratics (including potential bluestone sources) across Devon to Stonehenge. A thick, grounded Irish Sea ice sheet capable of such transport is incompatible with the restricted, low-elevation lacustrine basin documented here. Further work on the corrected map will allow precise contouring of the maximum ice-surface elevation in the Bristol Channel, providing a firmer limit on onshore incursion and strengthening (or ruling out) glacial-transport hypotheses.

References

Maw, G. (1864). On a supposed deposit of boulder-clay in North Devon. Quarterly Journal of the Geological Society of London, 20, 445–451.

Dewey, H. (1910). Notes on some igneous rocks from North Devon. Proceedings of the Geologists' Association, 21(4), 429–434.

Taylor, C.W. (1956). Erratics of the Saunton and Fremington areas. Report and Transactions of the Devonshire Association, 88, 52–64.

Arber, M.A. (1964). Erratic boulders within the Fremington Clay of North Devon. Geological Magazine, 101(3), 282–283.

Stephens, N. (1966). Some Pleistocene deposits in North Devon. Biuletyn Peryglacjalny, 15, 103–114.

Edmonds, E.A. (1972). The Pleistocene history of the Barnstaple area. Institute of Geological Sciences Report 72/2.

Kidson, C. & Wood, R. (1974). The Pleistocene stratigraphy of Barnstaple Bay. Proceedings of the Geologists' Association, 85(2), 223–237.

Wood, T.R. (1974). Quaternary deposits around Fremington. In: Straw, A. (Ed.), QRA Easter Field Meeting Handbook. Quaternary Research Association, Exeter, pp. 30–34.

Madgett, P.A. & Inglis, E.A. (1987). A re-appraisal of the erratic suite of the Saunton and Croyde areas. Transactions of the Devonshire Association, 119, 135–144.

Edmonds, E.A., Whittaker, A. & Williams, B.J. (1985). Geology of the country around Ilfracombe and Barnstaple. Memoir of the British Geological Survey, Sheets 277 and 293 (England and Wales). HMSO, London. ISBN 0 11 884364 8.

Hawkins, A.B. & Hawkins, S.C. (1990). Quaternary deposits in the Lake cutting of the Barnstaple Bypass, North Devon. Proceedings of the Ussher Society, 7, 301–303.

Croot, D.G., Gilbert, A., Griffiths, J. & van der Meer, J.J. (1996). The character, age and depositional environments of the Fremington Clay Series, North Devon. Quaternary Newsletter, 80, 1–15.

Cattell, A. (2003). Geological and geotechnical aspects of a landslip in the Fremington Clay, North Devon. Geoscience in South-West England, 10, 397–402.

Bennett, J.A., Cullingford, R.A., Gibbard, P.L., Hughes, P.D. & Murton, J.B. (2024). The Quaternary geology of Devon. Proceedings of the Ussher Society, 15, 84–130.

Daw, T., Ixer, R. & Madgett, P. (2026). A review of the Ramson Cliff erratic: evidence of high-level ice flow? Quaternary Newsletter, 167, 13–19. DOI: 10.64926/qn.20517.

Appendix A: Unified Borehole Register

The accompanying spreadsheet (Appendix_A_Unified_Boreholes.xlsx) presents the complete borehole register for all 31 boreholes referenced in this report: the 18 holes of the 1972 Brannam survey (BGS SS53SW62–79) and 13 additional boreholes from A39 Barnstaple Bypass site investigations and other archival BGS records.

For each borehole the register includes: BGS reference, BGS ID, corrected grid position (BNG), surface OD, overburden thickness, clay top OD, clay thickness, clay base OD, gravel OD (where reached), classification status, and descriptive notes. Brannam borehole depths are converted from imperial feet using 1 ft = 0.3048 m. Surface OD values are derived from the OS terrain model at corrected borehole positions.

Colour coding: green = lacustrine stratigraphy confirmed (diagnostic basal gravel reached or Fremington Clay positively identified); red = head above basin (clay top >38 m OD); amber = elevated margin or base unknown; grey = outside basin or no clay found. Of the 31 boreholes, 9 confirm lacustrine stratigraphy (8 Brannam gravel-bearing holes plus borehole 703458), 3 are classified as head above the basin (BH9–11), and the remainder are either on the basin margin with unconfirmed base, or dominated entirely by head deposits.

BH	BGS Ref	Easting (BNG)	Northing (BNG)	Surface OD (m)	O/B (ft)	Clay top (ft)	Clay thick (ft)	Max?	Gravel	Water	Clay quality
1	SS53SW62	253410	131580	25.80	20	NIL	—	N	no	no	No clay
2	SS53SW63	253460	131520	37.60	25	25	8	Y	no	no	Dirty
3	SS53SW64	253540	131600	35.10	13	13	14	Y	no	no	Dirty, worsens below 21ft
4	SS53SW65	253490	131700	32.80	11	11	19	Y	no	YES	Dirty
5	SS53SW66	253490	131880	27.66	16	16	16	Y	no	YES	Dirty
6	SS53SW67	253490	132000	24.00	13	13	12	N	YES	no	Dirty then gravel
7	SS53SW68	253740	131620	35.20	13	13	12	Y	no	no	Dirty
8	SS53SW69	254030	131620	34.70	11	11	18	Y	no	YES	Dirty
9	SS53SW70	253980	131360	41.20	9	9	20	Y	no	YES	Very dirty/earthy
10	SS53SW71	254050	131310	42.50	9	9	16	Y	no	no	Dirty/earthy
11	SS53SW72	254150	131250	42.80	9	9	32	Y	no	no	Dirty to 29ft; clean clay at 40ft
12	SS53SW73	252960	131490	36.50	12	12	18	N	YES	no	Earthy
13	SS53SW74	252950	131530	35.20	9	9	20	N	YES	YES	Good with finey
14	SS53SW75	252900	131520	35.10	9	11	14	N	YES	no	Good from 13ft
15	SS53SW76	252840	131610	31.60	9	15	10	N	YES	no	Mainly clean
16	SS53SW77	252830	131520	35.00	9	11	12	N	YES	no	Sandy/short
17	SS53SW78	253020	131920	25.20	11	11	20	N	YES	no	Good
18	SS53SW79	252990	131920	24.70	7	7	24	N	YES	no	Good; horseflesh at 17ft