1. Site Description
2. Geology
3. Access
4. General Assessment:
5. Associated Sites
6. Safety Information
7. Supplementary Information
8. Industrial History and Archaeology
9. Bibliography
10. Maps
11. Surveyors

This page still under construction.

Site Description

Grid Reference: NZ 751 198 to 783 191
BGS Sheet: 34
OS Sheet: 94

Site Status: Heritage Coast (Not RIGS, other references Nos. 55 and 80). Open access.

Description of Geodiversity: West of Boulby the cliffs rise to over 200m O.D. with the upper parts being formed of the old Boulby and Loftus Alum Quarries. These are SSSIs and, also for access reasons, are described separately. Between Boulby and Cowbar can be found superb sea cliffs and rocky foreshore (scar) with extensive Lias Group exposures. Much historical and industrial archaeological interest. The Cleveland Way passes along the cliff top.

View of Cowbar Nab from Staithes Harbour showing beds of the Staithes Formation capped by glacial 'till'.

Geology

With shallow dips, the strata that can be examined directly in situ are limited to the uppermost beds of the Redcar Mudstone Formation and the base of the Staithes Sandstone Formation. In the past, there were tracks down the cliffs that enabled geologists to study the full section easily.

• Whitby Mudstone Formation: This forms the upper part of the sea cliffs at Boulby with the alum shale quarry at about 130m O.D.
• Cleveland Ironstone and Staithes Sandstone Formations: These form the main cliff faces.
• Redcar Mudstone Formation: This forms the base of the cliffs and the scar. It is part of the Ironstone Shale, the uppermost, informal sub-unit, and consists principally of sandy, silty shale with conspicuous ironstone and calcareous beds and nodule bands (some remarkably like cannon balls).

Geomorphology: The cliffs for about 2 km to the west of Cowbar Nab are capped by glacial till, bedrock being at 40 to 50m O.D. Staithes Beck has cut a deep channel through the till in to the solid strata. On the coast, several landslips and rockfalls can be seen and, in contrast, examples of slow, gradual marine erosion. The marine erosion has been the subject of detailed studies by Agar (1960) and by Durham University in recent years.

Historical geology: This is the site of 19^th century measured sections by Rev. George Young, John Phillips, Lewis Hunton and others.

Industrial Archaeology:

• The cliffs form the seawards edge of Main Seam (Cleveland Ironstone Formation) underground workings of Boulby and Grinkle Ironstone Mines.
• With regard to the alum industry, the landing place (dock) and tunnel (leading to a shaft up to the alum house) are at Hole Wyke (NZ 762 193).

Access

Access to the scar is achieved from the west side of Staithes harbour. Visitors should park in the car park at the top of Staithes Bank (NZ 781 185), follow Staithes Lane north for c.400m before crossing Staithes Beck by bridge (NZ 781 189), then follow the road east to Cowbar Nab.

It is imperative to start no less than 2 hours before low tide and when sea conditions are reasonably calm. Please read the safety information given below and check tide times before setting off.

Access map for Boulby - Cowbar Foreshore showing suggested parking in Staithes and Mean High Water along cliff base.
(Click on map to enlarge.)

General Assessment:

This coastal section is not recommended for general geological studies owing to the access problems. However, the scar at Cowbar Nab is easy to visit at low tide; it forms a small part of the Geologists’ Association Guide No. 34 by Rawson and Wright (locality 1A, page 18 in 3rd edition). It is adventurous to visit the unique alum tunnel (about 2 km to the west) but this must on no account be entered. Children are best taken to the scar on the east side of Staithes, a world-renowned geological location.

Associated Sites

Boulby Alum Quarries (SSSI, Other reference no. 54);
Loftus Alum Quarries (SSSI, Other reference no. 53).
Hummersea (Other reference no. 51).

Safety Information

WARNING: When going along the scar it is imperative to be aware of the tide times and the sea conditions, the sea reaches the cliff foot at high water and the uneven nature of the scar here makes the tide’s inward progress difficult to predict.

The scar is likely to be wet and slippery and there is danger of falling rock from the unstable cliffs. Please remain at least 10 metres from the cliff foot at all times.

A boulder field makes going west beyond Hole Wyke difficult and further westerly progress should be avoided.

Disclaimer: Tees Valley RIGS Group cannot be responsible for the safety of anyone visiting this coastal site. The accompanying map was accurate when this trail was devised in 2011, but these cliffs are prone to landslip through natural processes and paths may be lost.

A NOTE ON FOSSILS

Please feel free to collect loose fossil specimens weathered from their places of original deposition. However, to enable future scientific study, and for the enjoyment of others who may follow in your footsteps, in situ fossils (i.e. those still embedded in their position of original deposition) should not be collected, but their positions noted and details passed on to TVRIGS, a local museum or other similar body.

Please follow the Countryside Code. Do not light fires. Take any litter home.

Supplementary Information

Geology

Structure: The succession is shown in the cross-section. The beds dip at a slight angle to the east at Cowbar Nab and then swing to a more southerly direction at Boulby and beyond with the result that, going westwards from Cowbar Nab, one is gradually descending the Redcar Mudstone Formation succession.

Section through Boulby Cliff showing the dip of the beds to the south.

Whitby Mudstone Formation (marine, in part anoxic): The Hard and Mulgrave Shale Members are present high up in Boulby Cliff. Fallen blocks, mainly of calcareous and sideritic nodules, can be examined on the scar.

Cleveland Ironstone Formation (shallow marine, even shoaled, oxidic, ironstone formed under slow sedimentation): The various ironstone seams can be seen high in the cliff face below Boulby Quarry and particularly the Pecten and Main Seams. Measured sections were made by various geologists using the tracks down to the beach (e.g Bewick, 1861, Chowns, 1968).

Staithes Sandstone Formation (shallow marine, with tidal influences and storm surges) This forms the main part of Cowbar Nab and the lower part of the cliffs westwards. It is about 25m in thickness and consists principally of siltstones and fine-grained sandstones. Beds 1 to 10 of Howarth’s (1955) sequence of 23 beds are accessible on the west side of the harbour and the remainder on the scar to the east. Measured sections are recorded by Tate and Blake (1876, referred to as ‘Colburn Nab’) and Barrow (1888). Modern detailed descriptions are available by, for example, Howarth (ibid), Howard (1985), Knox et al. (1990, Figure 21), Rawson and Wright (1995, Fig. 22) and Hesselbo and Jenkyns (1995, Figures 25 & 26).

Rawson and Wright (ibid) reported that, as seen at Cowbar Nab;

"the dominant lithology in the lower beds is an intensively bioturbated, argillaceous silty sandstone, with occasional thin (1-35 cm), almost unbioturbated fine sandstones. The latter exhibit delicately-preserved bedding structures, including parallel lamination, low-angle cross-lamination and wave ripple lamination. They have erosive bases, sometimes down-cutting to form small channels".

Knox et al. (ibid) comment that the beds form;

"a fining-up sequence of intensely bioturbated sandy siltstones and siltstones containing laterally discontinuous scour-like tempestites".

Fossils are mostly restricted to shelly lenses.

According to Hesselbo and Jenkyns (ibid) individual beds (and particularly the basal ‘Oyster Bed’) can be correlated closely with those exposed at Robin Hood’s Bay.

Redcar Mudstone Formation (marine): At Cowbar Nab the sequence is transitional and the top of the Formation is taken arbitrarily at the base of the ‘Oyster Bed’ (c.30 cm thick). The 20m logged sequence at Cowbar Nab (Knox et al. ibid, Hesselbo and Jenkyns ibid, their figure 25) consists of silty mudstone passing up to muddy siltstone with graded layers and very fine-grained sandstone with the ‘Oyster Bed’ at the top. Bed 21 (in Hesselbo and Jenkyns log at 20m below the ‘Oyster Bed’) is an ooidal ironstone also seen at a similar level in Robin Hood’s Bay and drawn to their attention by J. Senior. Tate and Blake (ibid) also refer to, what may be the same, ooidal ironstone, 8 or 9 inches (~0.2m) thick at Red Nab and Barrow to a ‘white ironstone’ 40 feet 6 inches (12.3m) below the ‘Oyster Bed’.

Chronostratigraphy (from Hesselbo and Jenkyns ibid):

• Staithes Sandstone Formation (Prodactylioceras davoei zone, Oistoceras figulinum subzone (22m), Androgynoceras capricornus subzone (~2m at base).
• Redcar Mudstone Formation (Prodactylioceras davoei zone, Androgynoceras maculatum subzone).

Fossils lists specific to these localities are in Tate and Blake (ibid) and Barrow (ibid) but note that most have since been renamed.

Geomorphology: For about 2 km west of Cowbar Nab, where the cliffs are capped by till, marine erosion consists of a combination of gradual wearing away of material giving rise in particular to a notch just above high water mark, with more substantial joint/fault/bedding-controlled fracturing resulting in rockfalls, and landslippage of the much less coherent till (Agar, 1960, Hemingway, 1982). Slight variations in competence and fracture patterns have resulted in the formation of several small coves and nabs.

Further west, below the higher Boulby Cliffs, there have been several landslips and rockfalls reported during and since the period of alum working that have carried away parts of the works and particularly the tracks down to the shore. Elsewhere, such as, for example, at the western end of the alum quarry (Sallow Tree Plain) the cliff erosion has been limited at least for the past 150 years.

The ground between the Boulby and Loftus Quarries illustrates how the original cliffs may have looked.

The erosion has been studied in recent years by D. Pybus (see Appleton, 2010) and a team from Durham University.

Historical geology: These sea cliffs and Boulby Quarry above are where several 19^th Century and, since then, other geologists haves made measured sections, making use of the tracks down to the shore. That by Louis Hunton (1836) is the most notable as he was one of the first to recognize the importance of collecting fossils in situ and relating the fossils found to the beds in which they occur.

View of the cliffs looking west from Sandy Wyke. Redhouse Nab can be seen slightly left of center.

Industrial History and Archaeology

Alum: The alum works dates from the 1650s. It closed in 1871. The alum house was at NZ 761 190 on the cliff top. There was a liquor conduit from the quarries and tracks and a shaft and tunnel from the house down to the dock at Hole Wyke (see section on Boulby Quarry). The history and industrial archaeology of the alum works has received much attention in recent years.

The tunnel entrance was lost to view for many years owing to landslippage and was rediscovered by Owen (1990) when it reappeared as a result of the eventual erosion of the loose, landslipped material. Owen and others (especially Morris and Whitlock, 2005) have made detailed surveys as more of the archaeology has been revealed. The entrance and associated ‘rooms’ have now been largely lost to the sea and the real start of the tunnel in bedrock is now revealed.
The microbiology of adjacent weathered shale has been studied by Cockell et al., 2011.

Western tunnel in the cliff at Hole Wyke, beneath the former Alum House as seen on 11th March 2007.

Ironstone: The Main Seam of the Cleveland Ironstone Formation has been worked extensively from:

1. Boulby Mine (1903-1934), miners’ drift entrance at NZ 754 191, and
2. Grinkle Mine (1865-1934) drift at NZ 762 177.
   (Boulby ironstone mine main haulage drift is now under the surface buildings of Cleveland Potash mine and the fan shaft is near the railway at NZ 757 179).

The Main Seam typically consisted of a Top Block ~1m, Shale 0.3m and Bottom Block 0.7m. Waste was tipped in to the sea from a drift exit on the sea cliff at NZ 762 190.

It is likely that there was some earlier ironstone working involving the collection of material from the beaches; 2 drifts in the cliff face are shown by the Geological Survey (Yorkshire sheet IX, 1878) at approximately NZ 753 194 and 755 196).

Current mining: Cleveland Potash mine (at NZ 762 184) is of major importance to the local and national economies. Production started in 1973 and production is of the order 1 million tonnes per year of potash as well as common salt. The workings extend over a wide area that includes Boulby Quarry at a depth of around 1100m below sea level.

The discharge tunnel shaft is on the cliff top at NZ 765 190.

Bibliography

Maps

Geological Survey Yorkshire Sheet IX SW, Rockcliff. scale 6 inches to 1 mile, 1878 (Ordnance Survey 1856).
Notes on the Lower Lias, Main Seam and Dogger. 13 Steeping pits at Sallow Tree with cisterns, various buildings and reservoirs. Rockcliff (Pithill) building shown with various paths and reservoirs.

Geological Survey Yorkshire Sheet IXX NW, Boulby, Runswick & Kettleness scale 6 inches to 1 mile, 1899 (Ordnance Survey 1856).
Detailed layout plan of alum house.

Geology & Geomorphology

Agar, R. 1960. Post-glacial Erosion of the North Yorkshire Coast from the Tees Estuary to Ravenscar. Proc. Yorks. Geol. Soc., 32, 409-428.
A valuable study of coastal erosion but subject to much, perhaps mistaken, criticism by Hemingway and others.

Appleton, A. 2010. The Ice Age and its Aftermath in Eastern Yorkshire: One possible interpretation of the evidence. Unpublished review, 33p. (in Whitby Lit. and Phil. Library).
An important contribution collating many views on the ice age and including data on marine erosion.

Barrow, G. 1888. The Geology of North Cleveland. Mem. Geol. Survey, H.M.S.O., London, 101p.
Pages. 9 and 12 show the Redcar Mudstone and Staithes Sandstone Formation sequences.

Bewick, J. 1861. Geological Treatise on the District of Cleveland in North Yorkshire, etc. Reid, Newcastle-upon-Tyne, 194p.
Page 191 shows the measured ironstone section.

Chowns, T. M. 1968. Environmental and diagenetic studies of the Cleveland Ironstone Formation in north-east Yorkshire. Thesis, University of Newcastle upon Tyne.
Page 337 has the measured section at Rockcliff.

Cockell, C. S. et al. 2011. Molecular characterization and geological microenvironment of a microbial community inhabiting receding shale cliffs. Microb. Ecol. , 61, 166-181. Samples taken from shale in the alum tunnel.

Fox-Strangways, C. 1892. The Jurassic Rocks of Britain, Volume 1. Yorkshire. Geol. Survey, H.M.S.O., London, 551p.
Similar to Barrow, 1888.

Hemingway, J. E. 1982. Chapter 1 in Prehistoric and Roman archaeology of north-east Yorkshire ed. D.A. Spratt. BAR British Series 104, 7-31.
A useful account of the eminent professor’s views on glaciation, cliff erosion, etc.

Hesselbo, S. P. And Jenkyns, H. C. 1995. A comparison of the Hettangian and Bajocian successions of Dorset and Yorkshire. From Taylor, P. D. (ed.), Field geology of the British Jurassic, Geological Society, London, 105-150.
Very detailed account. Includes lithic logs of ~20m of the Redcar Mudstone Formation, Ironstone Shale and all the Staithes Sandstone Formation at Staithes (page 138). They report long distance correlation of individual beds, for example, with those at Robin Hood’s Bay and, incredibly, Dorset.

Howard, A. S. 1985. Lithostratigraphy of the Staithes Sandstone and Cleveland Ironstone Formations (Lower Jurassic) of north-east Yorkshire. Proc. Yorks. Geol. Soc. 45, 261-275.
Detailed description, classificationand mode of formation.

Knox, R. W. O’B, Howard, A.S., Powell, J. H. And van Buchem, F. S. P. 1991. Lower and Middle Jurassic Sediments of the Cleveland Basin N. E. England: shallow marine and paralic facies seen in their sequence stratigraphic context. Field guide no. 5, 13th International Sedimentological Congress, Nottingham. 66p.
Day 2 (at Staithes) covers Cowbar Nab including ~6m of the Redcar Mudstone Formation.

Rawson, P. F. and Wright, J. K. 1995. Jurassic of the Cleveland basin, North Yorkshire. From Taylor, P. D. (ed.), Field geology of the British Jurassic, Geological Society, London, 173-208.
Excursion 5 covers Cowbar Nab.

Rawson, P. F. and Wright, J. K. 2000. The Yorkshire Coast. Geologists’ Association Guide No. 34, 3rd revised edition., 130p.
Itinerary 1, Staithes to Port Mulgrave is on pages 16 to 24 and locality 1A is Cowbar Nab.

Tate, R. and Blake, J. F. 1876. The Yorkshire Lias. John Van Voorst, London, 475p.
Pages 89-101, especially page 97, detail the A. capricornus (now P. davoei) zone. Pages 132and 133 show the ironstone section as seen on the path to the shore.

Historical geology

Goldring, D. 2007. Louis Hunton and Loftus Alum Works. Cleveland Industrial Heritage No. 21, 9-15.
Includes a copy of Hunton’s famous section emphasising points of industrial interest.

Hunton, L. 1836. Remarks on a section of the Upper Lias and Marlstone of Yorkshire, etc. Trans. Geol. Soc. London, 5, 215-220.
This is Hunton’s classic paper and includes his section at Boulby, undoubtedly the best by the early 19th Century geologists.

Phillips, J. 1829. Illustrations of the Geology of Yorkshire, etc. Part 1: The Yorkshire coast. Private publication, York, 192p. (2nd Edition 1835 and 3rd Edition 1875, edit R. Etheridge).
Classic account. Section no. 9 shows some detail at Boulby.

Torrens, H. S. and Getty, T. A. 1984. Louis Hunton (1814-1838). English Pioneer in Ammonite Biostratigraphy. Earth Sciences History, 3, 58-68.
A biography stressing the scientific importance of Louis Hunton.

Young, G. and Bird, J. 1822. A Geological Survey of the Yorkshire Coast. Clark, Whitby, 332p. (2nd edition 1828).
The classic measured section at Boulby is on page 134 in the 2nd Edition with the Whitby Mudstone Formation divided into 3 units.

Industrial History & Archaeology

Alum

Barton, P. 2004. Boulby Alum Works: Ways down to the beach. CIAS Newsletter No. 86, 13.
Refers to R. Jackson’s journal items from 1757 to 1783.

Chapman, S. K. 1975. Excavations at the Boulby Alum Works. Cleveland Industrial Archaeology Soc., 2, 23-47.
One of the first industrial archaeological accounts of an alum works.

Chapman, K. 2002. Boulby Alum Works. Chapter 6 in Steeped in History (ed. Miller, I.), North Yorks Moors National Park Authority, 61-74.
A revised account of the 1975 work with major additions and maps by English Heritage.

Featherston, G. R. 2004. Boulby: More on ways down to the beach. CIAS Newsletter No. 86, 13-15.
Adds to Goldring, 2004. See also 18, 19 for photos by J. K. Almond dated 5/8/2004

Goldring, D. 2004. Boulby Alum Works. Ways down to the beach. CIAS Newsletter No. 85, 12,13.
Discussion of the two alum roads to the beach and the shaft and tunnel.

Goldring, D. 2006. Boulby Alum Tunnel. Cleveland Industrial Heritage no. 19, 20.
Brief description of tunnel seen in 2004.

Jecock, M. 2009. A Fading Memory: the North Yorkshire coastal alum industry in the light of recent analytical field survey by English Heritage. Industrial Archaeology Review, 31, 54-73.
General review of the alum industry, including several pictures of Boulby.

Morris, C. H. and Whitlock, S. 2005. Boulby Alum Works’ Tunnel Revisited. Cleveland Industrial Archaeologist No. 30, 29-45.
A detailed industrial archaeological appraisal based on visits between August 2004 and January 2005.

Owen, J. S. 1990. The Tunnel and Shaft for Boulby Alum Works, some features briefly exposed. CIAS Newsletter No. 51, 3-6.
Report on first exposure of the tunnel since being covered by a landslip for many years.

Owen, J. S. 1991. As above, CIAS Newsletter No. 53, page 6.

Owen, J. S. 1995. Continuing clearance at Boulby alum works beach tunnel. CIAS Newsletter No. 62, 3-6.
Further comments.

Owen, J. S. (CIAS Editorial Board). 1998. Cleveland Ironstone. A Memorial to John Owen. CIAS & NYMNP Authority, 103p.
Pages 81-84 are on the Boulby tunnel, etc. based on the CIAS Newsletter references.

Quinn, K. 2009. Boulby Alum. The works diary of George Dodds, 1772-1788. Cleveland Industrial Archaeology Society Research Report No. 9, 76p.
A detailed, primary historical account of operations at Boulby.

Ironstone

Chapman, S. 1997. Boulby Ironstone Mine. Peter Tuffs, Guisborough, 40p.
Account of ironstone mining at Boulby and description of surface remains.

Marley, J. 1857. Cleveland Ironstone, etc. North of England IME Trans., 165-219.
Early, 19th Century ironstone working.

Tuffs, P. 1996. Catalogue of Cleveland Ironstone Mines. Peter Tuffs, Guisborough, 56p.
General details of the mines; booklet (Cleveland Ironstone Series) specifically on Grinkle Mine to be published during 2011.

Abandonment Plans (at Teesside Archives)

Boulby (1 plan), abandoned 2/7/1934. Reference No. 11232

Grinkle (4 plans), abandoned 21/6/1934. Reference No. 11261

Surveyors

Denis Goldring 2011

Please Note: Tees Valley RIGS Group cannot be held responsible for the content of external sites.

©2011 Tees Valley RIGS Group.

1. Mini Geo-Trail
2. Geo-Trail Map
3. Directions
4. Bibliography

Mini Geo-Trail

In the following route description, notes concerned with navigation are show in plum, descriptions of features able to be seen are in black and warnings are given in red.

Geo-Trail Map

Hummersea mini geo-trail location map showing numbered features of interest and parking (P). Adapted from Along the Scar (2001) (See references).
(Click on map to enlarge)

Directions

• Car Park: On the west side of the Skinningrove Beck mouth at NZ 712 201. Cross the village front and go over the bridge to reach the slipway on the eastern side of the valley.
  
  

  Looking east from the car park across the beck mouth at Skinningrove showing Hummersea Cliff.

  1. There are views of the village, the slag cliffs topped by the iron and steelworks, the incline and the jetty used for the export of pig iron. Further afield, Huntcliff can be seen with the present day mineral railway and the Guibal fanhouse (a much better view is gained by going a little way up the Cleveland Way steps).

 



Looking west from Hummersea Scar showing the slag cliffs (center left), jetty and Cattersty Cliff (midground) and Huntcliff (background).

• Go on to the beach and eastwards on the scar.
  2. The cliff line follows the strike (i.e. the beds are apparently horizontal as seen) and the same strata can be followed for some distance. The ironstone seams gradually appear as the cliffs become higher with the Main Seam at c.60m. At scar level the Redcar Mudstone Formation, silty shale, has thin beds and nodules of ironstone. Rounding Hummersea Point there are two deep clefts in the cliffs, the result of jointing and faulting. There are good examples of rutways on the scar.

 




Members of the RIGS Group and others explore the perched boulders between Skinningrove and Hummersea Steps.

• Continue on to Hummersea Beach, the steps and the ‘kiln’.
  3 The various remains of alum operations noted above can be viewed and the variety of pebbles appreciated.

 




Members of the RIGS Group and others discuss Hummersea Cliff from the beach below Hummersea Steps.

• Continue on the usually wet scar to the Old Gut.
  4. The remains of the dock can be investigated and the ironstone seams of the landslip.The seams have an apparent dip of c.80º to the south! The old line of a track up the cliff can be made out.
  Warning: It’s possible for the intrepid to go on eastwards a short way and, perhaps, find the ‘third dock’ but beware of the incoming tide; there is no easy way up the cliff short of Staithes.

 

• Return to Hummersea Beach and climb the steps and path to the Cleveland Way.
  5. View the geomorphology of this area (much of which has now been donated to Tees Valley Wildlife Trust). The scarp line of Saltwick Sandstone is set back from the coast and is paralleled underground by the subcrop of the Cleveland Ironstone Formation (see the geological map). The, therefore, deep embayment is infilled by till that is much landslipped on the seawards side. The Snilah Ponds, still shown on modern maps, are said to have been infilled by material from Boulby Potash Mine development.

 




View of Hummersea Cliff and Scar (foreground) with Skinningrove Beck mouth and Cattersty Cliff (beyond). The swing in the strike of the beds on the scar is clearly seen. Warsett Hill and Hunt Cliff are in the background with the Guibal fanhouse visible on the cliff top

• Return to Skinningrove along the cliff top following the Cleveland Way. Hummersea House, the home of the Louis Hunton, the famous geologist, is in view to the south-west prior to rounding Warsett Hill.

Disclaimer: Tees Valley RIGS Group cannot be responsible for the safety of anyone visiting the Hummersea site whilst following this geo-trail. The accompanying map was accurate when this trail was devised in 2011, but these cliffs are prone to landslip through natural processes and paths may be lost.

THINK SAFETY

We suggest that you check tide times and weather conditions before setting off, and do so only on a falling tide. Take great care and remain at least 10m away from the cliff base as the cliffs are prone to rock falls. Use appropriate safety equipment where necessary.

Bibliography

See Hummersea site description page »

©2011 Tees Valley RIGS Group.

PLEASE NOTE: Tees Valley RIGS Group cannot be held responsible for the content of external sites.

1. Site Description
2. Geology
3. Access
4. General Assessment:
5. Associated Sites
6. Safety Information
7. Supplementary Information
8. Geology
9. Industrial History and Archaeology
10. Literature References
11. Maps & Plans
12. Surveyors

Site Description

Grid Reference: NZ 755 195
BGS Sheet: 34
OS Sheet: 94
Forwarded as RIGS: 30/09/2003

Site Status: SSSI (RIGS Site Ref: RC5, Site No. 54 [ * Under Review * ]). Open access.

Please Note: The quarry is situated on private land, however spectacular views can be found by walking along the Cleveland Way and other adjacent public footpaths.

Description of Geodiversity: Extensive former alum quarry of great geological, scientific, historical and industrial archaeological interest. The Cleveland Way passes around the southern edge and along the top of the quarry back-wall that rises to over 200m O.D. The coastal scenery is impressive.

View of Boulby Quarries (foreground) showing Cowbar Nab near Staithes (background). Taken from the Cleveland Way above Sallow Tree Plain.

Geology

The quarries form the upper part of a virtually complete Jurassic succession ranging from the Lower Jurassic Redcar Mudstone Formation on the foreshore to the Middle Jurassic Saltwick Formation at the top. The quarried beds of interest to the alum industry constitute principally the Alum Shale Member of the Whitby Mudstone Formation. The beds exposed in the quarries are:

• Saltwick Formation: This forms the southern back-wall of the quarry, some 600m in length and up to 30m in height. It is formed predominantly of river channel sandstones. These exposures are difficult to reach and best examined more closely within the numerous fallen blocks.
• Dogger Formation: This Formation is about 1m thick and consists mainly of siliceous ironstone. It is sometimes absent as a result of washouts, and is now poorly exposed.
• Alum Shale Member: There are good exposures of the lower beds of shale (Whitby Mudstone Formation) which form the quarry floor especially at the western end.
• Reasons for SSI Status: Although the SSSI is named Boulby it actually includes both Boulby and Loftus Quarries. Two significant features, the murchisonae shale facies of the Dogger Formation and the finding of pterosaur remains in the Alum Shale, are at Loftus Quarries but it is likely that other reptilian remains were also found at Boulby.

Geomorphology: Several past and potential landslips and rockfalls can be seen and, in contrast, examples of slow, gradual sub-aerial cliff erosion.

Historical geology: This is the site of 19^th century measured sections by Rev. George Young, John Phillips, Lewis Hunton and others.

Industrial Archaeology:

• The quarry was a major alum site with at least two stages of development – mid-17^th to late-18^th century and late-18^th to late-19^th centuries. Across the site can be found the remains of calcining places, steeping pits, buildings, reservoirs, liquor conduits, etc. The stone revetments at the western end are most impressive.
• There are small ironstone trials of the Top Seam (Dogger Formation).
• The quarry is underlain by the extensive underground workings of the Main Seam (Cleveland Ironstone Formation) that are exposed along the sea cliff face.

Access

Access map for Boulby Quarries showing extent of SSSI and suggested parking.
(Click on map to enlage)

The easiest access is from the east along the Cleveland Way. A minor road off the A174 affords suitable parking.

General Assessment:

The quarry is an excellent venue for demonstrating Lower and Middle Jurassic geology, recent geomorphology, historical geology and industrial archaeology (alum and ironstone workings). The high cliffs require care.

Associated Sites

Boulby Sea Cliffs and Foreshore (North Yorkshire Heritage Coast, RC5, other reference 80.);
Loftus Alum Quarries (SSSI, other reference no. 53).

Safety Information

PLEASE NOTE: Due to the presence of high unfenced cliff faces we suggest that this site is not suitable for visits by unsupervised children. Please remain well away from the cliff edge and ensure any dogs are kept on a lead. Because of their unstable nature these cliffs must not, under any circumstances, be climbed.

Please follow the Country Code. Do not light fires. Take any litter home.

In situ fossils must not be collected, but their positions noted and details passed on to TVRIGS, a local museum or other similar body. Scattered fossils already weathered from the rock may be collected freely.

Supplementary Information

Geology

Structure: The succession is shown in the accompany section. The beds dip about 3° to the south.

Section through the cliff and quarry demonstrating the gentle dip of the beds.

Saltwick Formation (deltaic/alluvial): This forms the impressive back-wall of the quarry and consists principally of massive lenses of river channel sandstone. It is generally difficult to reach owing to fallen rock. Blocks, some extremely large, can be readily examined showing sedimentary structures such as cross-bedding and the imprints of plant remains.

Dogger Formation (marine incursion): This is about 1m in thickness and consists mainly of siliceous ooidal ironstone. However, at the eastern end it is described as ooidal siderite mudstone overlain by dark mudstone with similar mudstone nodules, as a clear result of lateral transition (Rastall and Hemingway, 1940). It is now poorly exposed. Blocks of ironstone can be examined that form a roughly laid wall by an old trial adit.

Alum Shale Member (marine): Some 10m of beds are exposed at various sub-quarry levels especially at the western (Sallow Tree Plain) end of the workings around the stone revetments. They consist of weathered, friable, grey, iron-stained, poorly bedded, flaky shale with vertically disposed jointing on the small scale. Fossils, chiefly poorly preserved belemnites, are uncommon but when seen may be present in clusters. Small acicular crystals of iron-stained gypsum are common. Occasional beds of lighter grey, calcareous, sometimes septarian, nodules can be found but, so far, Howarth’s (1962) detailed lithostratigraphic succession has not been elucidated. It is likely that the beds exposed belong to the lower part of the Alum Shale Member (the Hard Shale sub-unit) or even the upper part of the Mulgrave Shale Member.

Revetment walls at the west end of the site with Cowbar Nab in the background.

Geomorphology: The back-wall of the quarry has been subject to rock falls and there is now much debris at its foot. At the top, on the Cleveland Way there are open fissures with the cliffs being in a poor state. At quarry level on the seawards side there have been several landslips reported during and since the period of working that have carried away parts of the alum works and particularly the former tracks down to the shore. Elsewhere, such as for example at the Sallow Tree Plain (western end) steeping pits the cliff erosion has been limited. The ground between the Boulby and adjacent Loftus Alum Quarries illustrates how the original cliff profile looked.

Historical geology: Boulby Quarry and the sea cliffs beneath (making use of the tracks down to the shore) are where several 19^th century and, more recently, geologists such as Chowns made measured sections. That by Lewis Hunton (1836) is the most notable as he independently recognized the importance of collecting fossils in-situ, and relating the fossils found to the beds in which they occur bolstering the emerging concept of biostratigraphy.

View of Boulby Quarry and cliff as seen from Bias Scar toward Staithes.

Industrial History and Archaeology

Alum: The alum works was started in the 1650s at the eastern (Rockhole Hill) end of the quarry, redeveloped at the western (Sallow Tree Plain) end in 1784, and eventually closed in 1871. The alum house was about 0.5km to the south-east and, as well as tracks, there was a shaft and tunnel here connecting the house to the dock at Hole Wyke (see Boulby Sea Cliffs and Foreshore). The history and industrial archaeology of the alum works has received much attention in recent years (see references).

Ironstone: The Main Seam of the Cleveland Ironstone Formation has been worked extensively under the quarries from:

• (a) Boulby Mine, miners’ drift entrance at NZ 754 191, and
• (b) Grinkle Mine drift at NZ 762 177.

Boulby Ironstone Mine main haulage drift is now under the surface buildings of Cleveland Potash Mine, and the fan shaft is near the railway at NZ 757 179. The Main Seam typically consisted of a Top Block ~1m, Shale 0.3m and Bottom Block 0.7m. Waste was tipped in to the sea from a drift exit on the sea cliff at NZ 762 190. There are two trials of the Top Seam ironstone of the Dogger Formation, one within the quarries and one a short distance to the east (at NZ 758 190).

Current mining: Cleveland Potash Mine (at NZ 762 184) is of major importance to the local and national economies. Production started in 1973 and is of the order 1 million tonnes per year of potash (sylvinite) as well as rock salt (halite). The workings extend over a wide area that includes Boulby Quarry at a depth of around 1100m below sea level.

Literature References

Maps & Plans

Geological Survey Yorkshire Sheet IX SW, Rockcliff, scale 6 inches to 1 mile, 1878 (Ordnance Survey 1856).
Notes on the Lower Lias, Main Seam and Dogger. Shows 12 Steeping pits at Sallow Tree with cisterns, various buildings and reservoirs. Rockcliff (Pithill) building shown with various paths and reservoirs.

Geological Survey Yorkshire Sheet IXX NW, Boulby, Runswick & Kettleness, scale 6 inches to 1 mile, 1899 (Ordnance Survey 1856).
Shows outline plan of the alum house.

Ironstone Abandonment Plans (at Teesside Archives)

Boulby (1 plan), abandoned 2/7/1934. Ref. 11232
Grinkle (4 plans), abandoned 21/6/1934. Ref. 11261

Barrow, G. 1888. The Geology of North Cleveland. Mem. Geol. Survey, H.M.S.O., London, 101p.
Official memoir. Page. 9 shows the Main Seam ironstone section made on ‘the old road now slipped away’. Pages 42 and 43 show Dogger sections.

Chapman, S. K. 1975. Excavations at the Boulby Alum Works. Cleveland Industrial Archaeology Soc., 2, 23-47.
One of the first industrial archaeological accounts of an alum works.

Chapman, S. 2005. Boulby Alum Works Visit. C.I.A.S Newsletter No. 88, 11-17.
Industrial archaeological excursion guide.

Chapman, K. 2002. Boulby Alum Works. Chapter 6 in ‘Steeped in History’ (ed. Miller, I.), North Yorks Moors National Park Authority, 61-74.
A revised account of the 1975 work with additions and maps by English Heritage.

Fox-Strangways, C. 1892 The Jurassic Rocks of Britain, Volume 1. Yorkshire. Geol. Survey, H.M.S.O., London, 551p.
Similar to Barrow, 1888.

Goldring, D. 2001. Along the Scar. Peter Tuffs, Guisborough, 145p.
See pages 59 to 65.

Goldring, D. 2007. Louis Hunton and Loftus Alum Works. Cleveland Industrial Heritage No. 21, 9-15.
Includes a copy of Hunton’s famous section emphasising points of industrial interest.

Hunton, L. 1836. Remarks on a Section of the Upper Lias and Marlstone of Yorkshire, etc. Trans. Geol. Soc. London, 5, 215-220.
This is Hunton’s classic paper and includes his section at Boulby, undoubtedly the best by the early 19th Century geologists.

Jecock, M. 2009. A Fading Memory: The North Yorkshire coastal alum industry in the light of a recent analytical field survey by English Heritage. Industrial Archaeology Review, 31, 54-73.
General review of the alum industry, including several pictures of Boulby.

Marley, J. 1857. Cleveland Ironstone, etc. North of England IME Trans., 165-219.
Early, 19th Century ironstone working.

Miller, I. 2002. Steeped in History North York Moors NPA.

Osbourne, R. 1998. The Floating Egg Pimlico.

Phillips, J. 1829. Illustrations of the geology of Yorkshire, etc. Part 1 The Yorkshire coast. Private publication, York, 192p. (2nd Edition 1835 and 3rd Edition 1875, edit R. Etheridge).
Classic account. Section no. 9 shows some detail at Boulby.

Quinn, K. 2009. Boulby Alum: The works diary of George Dodds, (1772-1788). Cleveland Industrial Archaeology Society Research Report No. 9, 76p.
A detailed, primary historical account of operations at Boulby.

Rastall, R. H. & Hemingway, J. E. 1940. The Yorkshire Dogger, 1. The Coastal Region. Geol. Mag., 77, 177-197 & 257-275.
This is the only detailed description of the Dogger Formation for the Cleveland area. Pages 191 and 192 refer to Boulby sections and pages 263 and 264 to the petrography.

Tate, R. and Blake, J. F. 1876. The Yorkshire Lias. John Van Voorst, London, 475p.
Pages 132 and 133 show the ironstone section as seen on the path to the shore. Pages 170 and 175 detail the section in part of the Whitby Mudstone Formation.

Torrens, H. S. and Getty, T. A. 1984. Louis Hunton (1814-1838). English Pioneer in Ammonite Biostratigraphy. Earth Sciences History, 3, 58-68.
A biography stressing the scientific importance of Louis Hunton.

Tuffs, P. 1996. Catalogue of Cleveland Ironstone Mines. Peter Tuffs, Guisborough, 56p.
General details of the mines.

Young, G. and Bird, J. 1822. A Geological Survey of the Yorkshire Coast. Clark, Whitby, 332p. (2nd edition 1828).
The classic measured section at Boulby is on page 134 in the 2nd Edition with the Whitby Mudstone Formation divided into 3 subdivisions.

Surveyors

Denis Goldring 2011

©2011 Tees Valley RIGS Group.

Derived from the Latin Argilla – meaning ‘clay’, this group of rocks primarily comprise particles of the finest grade, including clay- and silt-sized clasts up to ¹/₁₆ mm in diameter. They may be divided into subclasses of shales, mudstones and siltstones.

Both shale and mudstone are composed of the finest particles of sediment less than ¹/₂₅₆ mm in diameter, and can be distinguished by the way in which they cleave. Shale is generally finely-laminated and fissile, able to be split easily along its bedding planes, mudstone on the other hand has no preferred axis of cleavage and tends to exhibit a ‘blocky’ fracture¹. Siltstone follows similar principles of cleavage but comprises grains between ¹/₂₅₆ mm and ¹/₁₆ mm in diameter.

Shales of the Whitby Mudstone Formation (grey) form the foreshore and lower cliff beneath Middle Jurassic sandstone (yellow) at Rosedale Wyke. The remains of Kettleness alum quarries form the headland in the background.

Clay minerals (alumino-silicates) make up the bulk of such rocks and may include kaolinite, illite, chlorite and montmorillonite-smectite. Argillites are rarely pure but include a mixture of minerals. For example the Alum Shale Member of the locally exposed Whitby Mudstone Formation contains all four of the above mentioned clay minerals plus pyrite (FeS₂), quartz (SiO₂), siderite (FeCO₃), calcite (CaCO₃), collophane (apatite), goethite (FeO(OH)), gypsum CaSO₄ • 2(H₂O), jarosite (KFe³⁺₃(OH)₆(SO₄)₂), mica, feldspar, zircon and anatase. The latter three minerals in only minor amounts.

Shales and mudstones may also frequently contain inclusions in the form of calcium carbonate, siderite or other minerals. These features form after deposition of the originating sediment during the process of lithifaction. They grow in-situ when minerals distributed through the body of the deposit are drawn toward a single point through ionic transportation. Often a shell fragment or fossil will provide a nucleating point around which the inclusion develops as the accreting mineral is drawn from the surrounding sediment. In the image below showing the Jet Rock Member at Rosedale Wyke, bedding can be seen to pass around the outside of weathered calcium carbonate nodules.

Laminations in the Jet Rock Member of the Whitby Mudstone Formation passing around weathered limestone nodules.

Argillites are all sedimentary in origin, their components being either water or wind-borne. They are the products of fairly low energy environments such as deep sea floor, tidal flats, lakes and (in the case of loessite – lithified wind-borne rock dust from a number of sources) continental environs. They may occur in a variety of colours ranging from the dark red-brown, blue-grey, or tea green Triassic deposits to the light brown or black Bituminous Shale and Jet Rock Members of the Lower Jurassic containing hydrocarbons.

Red-Brown Permo-Triassic mudstone as seen at Seaton Carew.

The fine-grained nature of argillites make them ideal for the preservation of detailed fossil specimens. One example of such excellent preservation is the enigmatic suite of remains discovered in the Burgess Shale of Canada by Charles Doolittle Walcott (1850-1927) in the early 20th century². These Middle Cambrian fossils were reappraised in the 1970s and found to represent the remains of creatures with a number of body plans previously unknown to science such as Marrella a kind of extinct crustacean.

Marrella - An extinct crustacean from the Burgess Shale of Canada with no modern day relatives.

Historically, argillites have been exploited locally for a number of reasons. Millions of tons of Lower Jurassic (Toarcian) Alum Shale were quarried and processed to serve the local alum trade at over twenty sites in and around the Tees Valley. At Ravengill, near Commondale, Middle Jurassic (Aalenian) mudstone was quarried and milled for the brick and tile trade.

When sedimentary argillites become altered (or metamorphosed) by heat and/or pressure to form rocks such as slate, hornfels, etc. the resulting fine-grained metamorphic rocks tend to be referred to as Pelites.

Notes

^[1] The ironstone miners of Cleveland had their own terminology for many kinds of rock and tended to refer to mudstone units inter-bedded with ironstone seams as shale.

^[2] If the anecdote concerning this discovery is to be believed, although C.D Walcott recovered the fossils from this lagerstatten, it was actually his horse which drew his attention to their presence.

PLEASE NOTE: TVRIGS Group cannot be held responsible for the content of external sites.

©2011 TVRIGS Group.

1. Introduction
2. Redcar Mudstone Formation
3. Staithes Formation
4. Cleveland Ironstone Formation
5. Whitby Mudstone Formation

Introduction

Column showing the succession of Lower Jurassic strata to be found on the coast and underlying country south of the River Tees.

Following the double inundation of the Late Triassic Rhaetic episode, the resulting noxious waters gradually ameliorated as the sea deepened and the area became a shallow arm of the Tethys Sea. Lower Jurassic rocks were deposited in a variety of marine environments ranging from shallow to deep sea floor. Collectively the Lower Jurassic succession is referred to as the Lias Group.

The earliest Jurassic beds in the Tees Valley crop out as scars on the foreshore at both Coatham and Redcar. Between here and Saltburn the rocks gradually disappear and the sandy beach is backed by thick deposits of much younger boulder clay. The scar at Saltburn marks reappearance of the solid rock and, in the cliffs, we see the second phase of deposition, the Staithes Formation, in the form of shallow marine sandstone and mudstone.
 
At Huntcliff, ironstone seams crop out at near the cliff top, some 90m above sea level, and a disused fan-house associated with Huntcliff Ironstone Mine can be seen on the cliff top. These seams mark the third phase of deposition in very shallow water. Rocks deposited in the final phase of Lower Jurassic sedimentation across the Tees Valley occur near to Hummersea and Boulby but also inland, for example along the escarpment of Guisborough Forest and at Slapewath. These rocks demonstrate an initial deepening of the Tethys, which later underwent an episode of low oxygen-content, before shallowing, culminating in the sea-floor being lifted above sea level, with the exposed surface suffering erosion and weathering to produce an episode of non-deposition, or unconformity

Redcar Mudstone Formation

Curving scars of Redcar Mudstone extend seaward near the lifeboat slipway at Redcar.

After the noxious conditions of the Triassic marine incursions, the sea deepened, became fully oxygenated, and a new era of sedimentation commenced with the Redcar Mudstone Formation. The Formation can be further sub-divided into Calcareous Shales, Siliceous Shales, Pyritous Shales and Ironstone Shales. The Redcar Mudstone is perhaps best known for its extinct fossil oysters or Devil’s Toe-Nails which wash up on the beaches in great numbers. At their base near Redcar these rocks comprise cycles of soft mudstone capped by thin, hard limestone often packed with well-preserved fossils. The Formation is well-exposed in coastal sections between Coatham and Staithes, or at Robin Hood’s Bay but seldom crops out inland due to a thick covering of till.

Staithes Formation

Staithes Formation at Cowbar Nab.

During deposition of the preceding Redcar Mudstone, waters became ever shallower and closer to a landmass causing a change in the type of sediment laid down on the sea floor. The Staithes Formation comprises fine-grained sandstones, thin mudstones, and bands of iron-rich nodules. Finely laminated sandstones, up to 0.8 metres thick, are frequently followed by units in which the bedding has been almost completely obliterated by burrowing organisms, a process know as bioturbation. Episodic storm surges resulted in ultimate deposition of finely-laminated beds known as striped beds or tempestites. The Staithes Formation is possibly the most fossiliferous rock to be found locally, with extensive oyster beds, belemnites, trace fossils left by many creatures that burrowed within the sediments, and much more. Sedimentary structures such as ancient ripple marks are also commonly seen within these rocks.

Cleveland Ironstone Formation

Cleveland Ironstone Formation at Jet Wyke east of Staithes.

This suite of rocks are famous for the part they played in the growth of Teesside during the mid- to late-1800s. Beds belonging to the Cleveland Ironstone Formation were deposited in conditions of varying water depth. They are made up of layers of grey silty mudstones with five distinct seams of ironstone, the latter deposited during episodes of low sediment input, in a sea rich with life. Fossils are common and usually well-preserved in the ironstones. The seams, in order of deposition, have been dubbed Avicula, Raisdale,Two-foot, Pecten and Main Seams. They increase in both thickness and grade upwards culminating in the Main Seam which possesses an iron content of 33% and maximum thickness of 4.8 metres in the Eston Hills.
 
Cleveland ironstone often demonstrates an oolitic texture, the rock comprising a high percentage of structures around a millimetre in diameter known as ooids. These are concentrically ringed, sub-spherical, particles of berthierine, an iron silicate mineral and siderite (iron carbonate). Ooids form through the action of wave energy rolling around small particles of sand, shell, or some other suitable nucleating matrial, upon which are precipitated minerals from the surrounding water. Because of their mode of formation the presence of ooids generally indicates deposition in shallow water. Cleveland ironstone is blue-grey, or grey-green in colour when fresh and somewhat mottled when oolitic, weathering to a rusty red-brown.

Whitby Mudstone Formation

Grey mudrock of the Whitby Mudstone Formation (Alum Shale Member) as seen in Loftus Quarry.

Following deposition of the Cleveland Ironstone the sea reached depths not experienced across the area since Permian times. This led to deposition of the Whitby Mudstone Formation which consists of, in ascending order, the Grey Shale, Mulgrave Shale, Alum Shale and Cement Shale Members. A few younger rock units, in the shape of the Peak Mudstone, Rosedale Oolite and Foxcliff Siltstone Members, are not present except in a few pockets of the North York Moors having either not been deposited or removed by erosion. Initially, sea level change was gradual and there is little difference between the Grey Shale Member of the Whitby Mudstone Formation and those of the preceding Cleveland Ironstone Formation.

Succeeding the Grey Shale is the Mulgrave Shale Member which comprises, in ascending order, the much quoted informal units Jet Rock, Top Jet Dogger, Bituminous Shales and the Ovatum Band. A double band of pyrite-skinned concretions often containing the rare ammonite Ovaticeras.

The Jet Rock consists of beds of dark finely-laminated shale containing pyrite. This shale smells strongly of mineral oil when freshly broken. Seasonal falls of dead plankton from the upper waters are responsible for the presence of the oil. Seams of jet can be found which form where waterlogged tree trunks became buried within the oxygen-depleted sea floor mud.

The Top Jet Dogger is a discontinuous thin limestone best viewed in coastal exposures. This is succeeded by the Bituminous Shales which have similar characteristics to the Jet Rock. Shallower seas led to greater oxygenation of the waters and deposition of beds known as the Alum Shale Member, informally divided, in ascending order, into the Hard, Main Alum and Cement Shales. Many large reptile fossils (Plesiosaurs, Ichthyosaurs, crocodiles, and even a Pterosaur) have been recovered from these beds some of which are on display in local museums.

In the North York Moors area the Alum Shale Member is usually succeeded by the Cement Shales. These beds differ little in appearance from the Alum Shales, but contain numerous large limestone nodules once processed for hydraulic (Roman) cement.

« Triassic                               Middle Jurassic »

©2011 Tees Valley RIGS Group.

Shown below is a representation of the rocks underlying the Tees Valley and Darlington districts in Northeast England. The diagram depicts the relative thickness of the different systems. Absolute ages are given alongside. Click on the different areas to view more details about a particular time period.

Geological column showing the relative thickness and absolute ages of rocks underlying the Tees Valley and Darlington.

Marker on the Cleveland Way east of Saltburn. Huntcliff can be seen in the background.

Stretching along the coast between Redcar and Filey can be found a sequence of rocks that have been highly acclaimed by generations of geologists:

“In no part of England is the relation of the surface topography to the nature of the underlying rocks more instructively displayed than in this district; nor can the succession of a considerable part of the Jurassic series of formation be anywhere more advantageously examined than along the coast-sections…”
[Archibald Geikie, Director of the Geological Survey. (1888)]

Jurassic deposits locally total around 560 metres of strata which were deposited between c.199 million and 161 million years ago in environments which varied between deep sea, populated by a variety of distinctive marine creatures, to well-vegetated river delta upon which reptiles once roamed.

An example of the locally abundant ammonite Dactylioceras commune which has been split and polished to show crystals of calcite filling the internal chambers.

Geologists long-ago realised that similar rocks in diverse areas could be correlated by examining their fossil content. One of the earliest to realise this was Lewis Hunton (1814-1838), son of a Loftus alum-worker who studied remains of long extinct sea creatures in Jurassic rocks at Hummersea and Boulby. As far as correlation of different rock units is concerned, the most useful fossils turned out to be the coiled shells of many species of ammonite. Ammonites are now-extinct creatures related to modern day squid and octopuses (Cephalopods). Modern geologists can identify over sixty ammonite zones in the Lower Jurassic alone, which finely subdivide the various strata and make relationships between them much easier to understand.

Table showing the various sub-divisions of the Jurassic along with ammonite zones able to be seen within the Tees Valley and North Yorkshire.
Adapted from The Yorkshire Coast by P.F. Rawson & J.K. Wright (1992).

Lower Jurassic »

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©2011 Tees Valley RIGS Group.

1. Site Description
2. Site Map
3. Site Assessment
4. Surveyors

Grid Reference NZ 7784 192
BGS Sheet 34
OS Sheet 94
Forwarded as RIGS Part of Skinningrove to Staithes Coast 30/09/2003

Site Description

Site Status Part of the Heritage Coast
Description of Geodiversity Costal cliff nab exposure consisting of the Staithes sandstone formation which is the type locality. The foreshore to the west of the coastal defences consists of Redcar mudstone
Literature References The Yorkshire Coast – Peter Rawson & John Wright 1992
The Regional Coastline of Yorkshire – J.W.Steers 1967

Site Map

Site Assessment

Surveyors

Andrew Carter, Andrew Cooper, Carl Rees-Davies

1. Site Description
2. Site Map
3. Site Assessment
4. Surveyors

Grid Reference NZ 690 228
BGS Sheet 34
OS Sheet 94
Forwarded as RIGS Part of Saltburn to Skinningrove Coast 30/09/2003

Site Description

Site Status SNCI
Description of Geodiversity Wave washed platform and cliffs revealing Redcar mudstone formation at the base overlain by Staithes sandstone in the cliffs. Cleveland ironstone in upper part of cliffs, all capped by glacial till
Literature References Along the Scar – Denis Goldring 2001
The Regional Coastline of Yorkshire – J.W.Steers 1967

Site Map

Site Assessment

Surveyors

Denis Goldring

1. Site Description
2. Site Map
3. Site Assessment
4. Surveyors

Grid Reference NZ 615 253
BGS Sheet 34
OS Sheet 93
Forwarded as RIGS 30/09/2003

Site Description

Site Status SSSI
Description of Geodiversity Wave washed platform of Redcar mudstone. Locality reveals the lowest Lias group exposure in the Tees Valley
Literature References Along the Scar – Dennis Goldring 2001
The Regional Coastline of Yorkshire – J.W.Steers 1967

Site Map

Site Assessment

Surveyors

Andrew Carter, John Waring