Geology of County Durham

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This article describes the geology of the ceremonial county of Durham. It includes the boroughs of Darlington, Hartlepool and Stockton-on-Tees but not those former northeastern parts of the county which are now in the county of Tyne and Wear.

The geology of County Durham in northeast England consists of a basement of Lower Palaeozoic rocks overlain by a varying thickness of Carboniferous and Permo-Triassic sedimentary rocks which dip generally eastwards towards the North Sea. These have been intruded by a pluton, sills and dykes at various times from the Devonian Period to the Palaeogene. The whole is overlain by a suite of unconsolidated deposits of Quaternary age arising from glaciation and from other processes operating during the post-glacial period to the present. [1] The geological interest of the west of the county was recognised by the designation in 2003 of the North Pennines Area of Outstanding Natural Beauty as a European Geopark.

Contents

The word 'geology' may be traced back to a coinage of Richard de Bury who was a Bishop of Durham in the 14th century. He introduced the term geologia in his work The Philobiblon which he explained as 'the earthly science'. [2] :8

Ordovician

The oldest rocks at or near the surface within County Durham are Ordovician age (485 - 443 Ma) Skiddaw Group rocks found in a small inlier near Cronkley Fell in upper Teesdale. They are recorded as the Skiddaw Slates, better known from the Lake District 50 km to the west. A small quarry in these phyllites was worked at one time to make slate pencils. [3] Overlying these are pyroclastic rocks thought to belong to the Borrowdale Volcanic Group. [4]

No rocks from the succeeding Silurian Period (443 - 419 Ma) are seen at outcrop in the county.

Devonian

No rocks of Devonian age (419 - 359 Ma) are seen at outcrop in the county though a pluton, the Weardale Granite forming the North Pennine Batholith was intruded into Lower Palaeozoic rocks around 410 million years ago during the Devonian Period. [2] :19 It forms a part of the larger 'North of England Plutonic Suite', whose members (which include the granites at Shap and Skiddaw) were emplaced during the Caledonian Orogeny. [5] The buoyancy of this batholith (it is less dense than the rock into which it was intruded) is considered to be responsible for the existence of the Alston Block which coincides with the North Pennines and which is essentially an eastward dipping horst bounded to the west (outside of County Durham) by the Pennine Fault System, to the north by the Stublick and Ninety Fathom faults (in Northumberland) and by the Butterknowle Fault and Stainmore Trough to the south. [6]

Carboniferous

There is a thick succession of rocks in County Durham which originated during the Carboniferous Period (359 - 299 Ma). The detail of the rock succession varies from one part of the county to another and in no one location is the entire sequence detailed below in place. The sequence over the Alston Block is generally thinner than elsewhere.

The western half of the county forms a part of the Pennine range of hills which are formed largely by the sandstones and limestones of the Great Scar Limestone and overlying Yoredale groups. Further east it is the younger Coal Measures rocks which are found at the surface. Further east again the Carboniferous succession is overlain by younger rocks but they are present at increasing depth to the North Sea coast and beyond.

Note that the subdivision of the British Carboniferous rock sequence has undergone considerable revision in recent years and many traditional sequence names are now obsolete in formal use, though of course they remain widespread in the literature. What is now referred to as the Pennine Coal Measures Group would once have been referred to simply as the 'Productive Coal Measures' and the Yoredale Group was the 'Yoredale Series'. The 'Millstone Grit' of County Durham (minus the 'Great Limestone Member') has been renamed as the 'Stainmore Formation', having also been referred to somewhat confusingly as the Stainmore Group at one time. [7]

A feature of much of the Carboniferous succession in northern England is its cyclicity which has involved regular changes between marine deposition and sedimentation from rivers. The phenomenon is manifest as cyclothems and is especially prominent in the Yoredale Group sequence.

Great Scar Limestone Group

A part of the Carboniferous Limestone Supergroup, the Great Scar Limestone Group consists of a number of different formations except over the Alston Block where a 107m thickness of largely Asbian age limestones and sandstones occurs and is known as the Melmerby Scar Limestone Formation. [8]

Limestone was widely quarried for the production of lime for agriculture and lime mortar for building. Industrial scale quarrying accompanied the growth of the iron and steel industries but has since declined. The Frosterley Marble, a bituminous coraliferous limestone once worked at Harehope Quarry in Weardale is used as a decorative stone and can be found in many churches in the region. Concentrations of such corals as Dibunophyllum bipartitum and of brachiopod remains contribute to its attractiveness when sections are polished. [9] [2] :40

Yoredale Group

Rocks assigned to the Yoredale Group overlie the Carboniferous Limestone succession. The Group is subdivided into a lower/older Alston Formation and a higher/younger Stainmore Formation. The former is largely of Brigantian age whilst the latter is of Asbian/Brigantian to Yeadonian age. The latter is broadly equivalent to the Millstone Grit of the central and southern Pennines. Note that in northeast England some hard rock units are traditionally described as 'sills', a local term for a hard band of rock of whatever origin. Nowadays geologists reserve the term for flat-lying igneous intrusions such as the Whin Sill which is described below.

Coal Measures

Overlying the Yoredale Group rocks is a thick sequence of Coal Measures across which the Durham Coalfield developed. The sequence in County Durham is divided into Lower, Middle and Upper formations. Each of the three are dominated by mudstones but contain abundant sandstones and coal seams. Ironstone bands occur in the lower part of the sequence. At least eleven marine bands (shelly mudstones in general) occur within the Coal Measures. Of these, the 'Quarterburn' marine band defines the base of the Lower Coal Measures Formation, the 'Harvey' marine band defines its junction with the overlying Middle Coal Measures Formation and the 'Down Hill' marine band defines the latter's junction with the Upper Coal Measures Formation. The Quarterburn, Harvey and Down Hill marine bands correlate with the standard Subcrenatum, Vanderbeckei and Cambriense marine bands of elsewhere. The top of the entire Coal Measures sequence is an erosion surface. [10]

Over the Alston Block the middle and upper Coal Measures are missing. Similarly in the Stainmore Trough on the Yorkshire border, both the upper part of the Middle and the entire Upper Coal Measures are absent. The rank of coal increases in the west, a result of the heating of these strata by the Weardale Granite. Some such seams are semi-anthracites. Workings for coal date back centuries though the height of the industry was the nineteenth century. There are no deep pits remaining in the county though opencasting continues.

Various of the county's Coal Measures sandstones have been quarried for building stone, for example the Low Main Post sandstone in Durham which was used in the construction of the city's cathedral.

Late Carboniferous intrusive rocks

The 'Hett Subswarm' of tholeiitic quartz-dolerite dykes run WSW-ENE across country to the south of Durham. The subswarm includes the Hett Dyke and Ludworth Dyke amongst others which cut Coal Measures rocks in a WSW-ENE alignment but do not pass into the overlying Permian succession. [11]

Permian and Triassic

As with the Carboniferous sequence, the subdivision of the British Permian (299 - 252 Ma) and Triassic (252 - 201 Ma) has been considerably revised in recent years. Traditional sequence names have been replaced in formal use by new names, though the older names are frequently encountered in books and on maps. The full sequence of Permian and Triassic rocks forming the New Red Sandstone Supergroup locally is this (uppermost/youngest first):

The Yellow Sands Formation comprises aeolian dune-bedded sandstones. The Yellow Sands Formation continues to be worked for building sand. These are overlain by the thin bituminous limestones of the 'Marl Slate' representing the start of a series of inundations of the area by rising sea levels. It contains abundant fish remains. [2] :20

The sequence from the Marl Slate up to and including the Seaham Formation was formerly known as the Magnesian Limestone. The 'Zechstein Group' replaced the former Don, Aislaby, Teesside, Staintondale and Eskdale groups. Several of these units have proved economically valuable. Anhydrite was sourced beneath Hartlepool and gypsum near Darlington. The Magnesian Limestone forms a broken west-facing scarp running from the western edge of Sunderland southwards through Houghton-le-Spring and Hetton-le-Hole to Coxhoe where its outcrop is offset to the west by the Butterknowle Fault. English Nature has defined this part of the county east of the scarp where the sequence is exposed at or near the surface, as the 'Durham Magnesian Limestone Plateau' in its assessment of 'character areas'. [12] The occurrence of gypsum and anhydrite reflects the extreme nature of the evaporation of the shallow Zechstein Sea on occasion though such evaporites are economically valuable. They also present constraints on development as ongoing subterranean solution of these deposits causes occasional catastrophic ground collapse. Similar solution in Palaeogene times has created 'collapse breccias' of overlying strata.

Dolomite from the Roker Formation has been quarried for building construction along the Durham coast. It has sometimes been referred to as 'Cannonball Rock' due to the appearance of calcitic concretions in certain beds. St Oswald's Church in Hartlepool is constructed from this stone. [13]

Permian intrusive rocks

The Whin Sill and associated igneous dykes were intruded into the existing sedimentary sequence during the early Permian around 295 Ma. [2] The thickness of the quartz-dolerite sill averages about 30m. The sill underlies the larger part of the county at depth and appears to extend beneath the North Sea to the east. Thermal metamorphism has altered the surrounding strata, the 'country rocks', to a distance of tens of metres or more. One such is the Sugar Limestone of upper Teesdale which weathers in characteristic fashion and hosts a rare assemblage of plants. Mudstones in contact with the sill have been altered into hornfels, known locally as 'whetstone'. [2] :20 The presence of the Whin Sill gives rise to High Force where the River Tees drops in spectacular fashion over this erosion-resistant rock. The Little Whin Sill is a thinner, more geographically restricted intrusion of dolerite of similar age outcropping in upper Weardale. A quarry near High Force in upper Teesdale works the dolerite (or 'whinstone') of the Whin Sill for roadstone, aggregate and as larger blocks for coastal protection purposes.

Northern Pennine Orefield

The Northern Pennine Orefield comprises an extended network of veins and 'flats' developed within the Carboniferous sedimentary sequence and is considered one of the finest examples of Mississippi Valley type orefields. Epigenetic mineralisation (i.e. mineralisation at a shallow level) of veins and faults took place shortly after emplacement of the Whin Sill at the start of the Permian Period. [2] :20 Mining for lead, copper and zinc has taken place over several centuries across these uplands. [14] [15]

Palaeogene

Volcanism centred on western Scotland took place during the Palaeogene Period and resulted in the intrusion of innumerable dykes, one of which is the Cleveland Dyke which extends from Galloway through County Durham to the North York Moors. This intrusion of basaltic andesite which is up to 30m wide in places has been dated to 55.8+/- 0.9Ma [16]

Structure

The broad structure of the Alston Block has been described in the Devonian section above. The block is itself cut north to south a by a complex structure known as the 'Burtreeford Disturbance' which comprises both faults and folds. [17] To the east of the block the cover of late Palaeozoic and early Mesozoic rocks dip into the North Sea Basin.

Quaternary

Glacial legacy

Much of the county is mantled with a layer of glacial till though this is thinner on the higher ground in the west. There are also spreads of glacially derived sand and gravel, especially across part of the lower ground in the east. Alluvium deposited by rivers occupies the floors of valleys such as that of the Wear whilst river terraces are frequent in the Tees valley. Lacustrine clays and silts occur in parts of the east where for example, towards the end of the last ice age, Glacial Lake Wear and Glacial Lake Edderacres formed as drainage eastwards was blocked by an icesheet occupying the North Sea. [18]

Post-glacial

Peat has developed extensively across the higher ground of the North Pennines. A variety of coastal deposits are found around the Tees estuary and up the coast to Hartlepool and beyond. [19]

Geoconservation and Geotourism

Some locations in County Durham are afforded statutory legal protection against adverse developments through being designated as one or more of the following:

Local geological sites

A geodiversity audit of County Durham produced many locations which are now afforded recognition as 'Local geological sites' (formerly referred to as 'Regionally Important Geodiversity Sites' or simply 'RIGS'. [20]

Local nature reserves

LNRs may be designated for their biological or geological interest. In any case, more often than not, the biological interest is dependent upon the geological interest as at Wingate Quarry LNR north of Trimdon Grange village where 'Magnesian Limestone grassland' may be found [21]

Sites of Special Scientific Interest

Numerous SSSIs include citations referring to their geological interest. The extensive Moorhouse and Cross Fell SSSI (shared with Cumbria) is one of the most important for a range of subjects. Natural England and other conservation bodies own and manage these locations. The Durham Coast is one such which is designated in part for its coastal geomorphology.

Bodies such as the North Pennines AONB Partnership and Durham County Council have published local geodiversity action plans (or 'LGAPs') which summarise an area's geological interests and propose various measures to conserve what is perceived to be valuable. [22]

North Pennines AONB and Geopark

The North Pennines AONB was designated as Britain's first European Geopark in 2003 partly in acknowledgement of its geological and geomorphological interest. The AONB and Geopark extend beyond the boundaries of County Durham to include parts of Northumberland and Cumbria. [23]

See also

Further reading

British Geological Survey 1:50,000 scale geological map series sheets (England and Wales) 19 - 21, 25 - 27, 31 - 33, 40 & 41 and accompanying memoirs.

Related Research Articles

<span class="mw-page-title-main">North Pennines</span> Range of hills in northern England

The North Pennines is the northernmost section of the Pennine range of hills which runs north–south through northern England. It lies between Carlisle to the west and Darlington to the east. It is bounded to the north by the Tyne Valley and to the south by the Stainmore Gap.

The geology of Shropshire is very diverse with a large number of periods being represented at outcrop. The bedrock consists principally of sedimentary rocks of Palaeozoic and Mesozoic age, surrounding restricted areas of Precambrian metasedimentary and metavolcanic rocks. The county hosts in its Quaternary deposits and landforms, a significant record of recent glaciation. The exploitation of the Coal Measures and other Carboniferous age strata in the Ironbridge area made it one of the birthplaces of the Industrial Revolution. There is also a large amount of mineral wealth in the county, including lead and baryte. Quarrying is still active, with limestone for cement manufacture and concrete aggregate, sandstone, greywacke and dolerite for road aggregate, and sand and gravel for aggregate and drainage filters. Groundwater is an equally important economic resource.

<span class="mw-page-title-main">Whin Sill</span> Layer of dolerite rock in northern England

The Whin Sill or Great Whin Sill is a tabular layer of the igneous rock dolerite in County Durham, Northumberland and Cumbria in the northeast of England. It lies partly in the North Pennines Area of Outstanding Natural Beauty and partly in Northumberland National Park and stretches from Teesdale northwards towards Berwick.

<span class="mw-page-title-main">Geology of England</span> Overview of the geology of England

The geology of England is mainly sedimentary. The youngest rocks are in the south east around London, progressing in age in a north westerly direction. The Tees–Exe line marks the division between younger, softer and low-lying rocks in the south east and the generally older and harder rocks of the north and west which give rise to higher relief in those regions. The geology of England is recognisable in the landscape of its counties, the building materials of its towns and its regional extractive industries.

<span class="mw-page-title-main">Geology of Wales</span> Overview of the geology of Wales

The geology of Wales is complex and varied; its study has been of considerable historical significance in the development of geology as a science. All geological periods from the Cryogenian to the Jurassic are represented at outcrop, whilst younger sedimentary rocks occur beneath the seas immediately off the Welsh coast. The effects of two mountain-building episodes have left their mark in the faulting and folding of much of the Palaeozoic rock sequence. Superficial deposits and landforms created during the present Quaternary period by water and ice are also plentiful and contribute to a remarkably diverse landscape of mountains, hills and coastal plains.

<span class="mw-page-title-main">Geology of Yorkshire</span>

The Geology of Yorkshire in northern England shows a very close relationship between the major topographical areas and the geological period in which their rocks were formed. The rocks of the Pennine chain of hills in the west are of Carboniferous origin whilst those of the central vale are Permo-Triassic. The North York Moors in the north-east of the county are Jurassic in age while the Yorkshire Wolds to the south east are Cretaceous chalk uplands. The plain of Holderness and the Humberhead levels both owe their present form to the Quaternary ice ages. The strata become gradually younger from west to east.

<span class="mw-page-title-main">Marros Group</span> Geological term for rock in south Wales

The Marros Group is the name given to a suite of rocks of Namurian age laid down during the Carboniferous Period in South Wales. These rocks were formerly known as the Millstone Grit Series but are now distinguished from the similar but geographically separate rock sequences of the Pennines and Peak District of northern England and northeast Wales by this new name.

The geology of Monmouthshire in southeast Wales largely consists of a thick series of sedimentary rocks of different types originating in the Silurian, Devonian, Carboniferous, Triassic and Jurassic periods.

<span class="mw-page-title-main">Magnesian Limestone</span> Suite of carbonate rocks in England

The Magnesian Limestone is a suite of carbonate rocks in north-east England dating from the Permian period. The outcrop stretches from Nottingham northwards through Yorkshire and into County Durham where it is exposed along the coast between Hartlepool and South Shields. The term has now been discontinued in formal use though it appears widely in popular and scientific literature on the geology of northern England.

The geology of Lancashire in northwest England consists in the main of Carboniferous age rocks but with Triassic sandstones and mudstones at or near the surface of the lowlands bordering the Irish Sea though these are largely obscured by Quaternary deposits.

The geology of Merseyside in northwest England largely consists of a faulted sequence of Carboniferous Coal Measures rocks overlain in the west by younger Triassic and Permian age sandstones and mudstones. Glaciation during the present Quaternary Period has left widespread glacial till as well as erosional landforms. Other post-glacial superficial deposits such as river and estuarine alluvium, peat and blown sand are abundant.

The geology of Tyne and Wear in northeast England largely consists of a suite of sedimentary rocks dating from the Carboniferous and Permian periods into which were intruded igneous dykes during the later Palaeogene Period.

The Great Scar Limestone Group is a lithostratigraphical term referring to a succession of generally fossiliferous rock strata which occur in the Pennines in northern England and in the Isle of Man within the Tournaisian and Visean stages of the Carboniferous Period.

The geology of West Sussex in southeast England comprises a succession of sedimentary rocks of Cretaceous age overlain in the south by sediments of Palaeogene age. The sequence of strata from both periods consists of a variety of sandstones, mudstones, siltstones and limestones. These sediments were deposited within the Hampshire and Weald basins. Erosion subsequent to large scale but gentle folding associated with the Alpine Orogeny has resulted in the present outcrop pattern across the county, dominated by the north facing chalk scarp of the South Downs. The bedrock is overlain by a suite of Quaternary deposits of varied origin. Parts of both the bedrock and these superficial deposits have been worked for a variety of minerals for use in construction, industry and agriculture.

The geology of Northumberland in northeast England includes a mix of sedimentary, intrusive and extrusive igneous rocks from the Palaeozoic and Cenozoic eras. Devonian age volcanic rocks and a granite pluton form the Cheviot massif. The geology of the rest of the county is characterised largely by a thick sequence of sedimentary rocks of Carboniferous age. These are intruded by both Permian and Palaeogene dykes and sills and the whole is overlain by unconsolidated sediments from the last ice age and the post-glacial period. The Whin Sill makes a significant impact on Northumberland's character and the former working of the Northumberland Coalfield significantly influenced the development of the county's economy. The county's geology contributes to a series of significant landscape features around which the Northumberland National Park was designated.

The geology of Northumberland National Park in northeast England includes a mix of sedimentary, intrusive and extrusive igneous rocks from the Palaeozoic and Cenozoic eras. Devonian age volcanic rocks and a granite pluton form the Cheviot massif. The geology of the rest of the national park is characterised largely by a thick sequence of sedimentary rocks of Carboniferous age. These are intruded by Permian dykes and sills, of which the Whin Sill makes a significant impact in the south of the park. Further dykes were intruded during the Palaeogene period. The whole is overlain by unconsolidated sediments from the last ice age and the post-glacial period.

The geology of the Gower Peninsula in South Wales is central to the area's character and to its appeal to visitors. The peninsula is formed almost entirely from a faulted and folded sequence of Carboniferous rocks though both the earlier Old Red Sandstone and later New Red Sandstone are also present. Gower lay on the southern margin of the last ice sheet and has been a focus of interest for researchers and students in that respect too. Cave development and the use of some for early human occupation is a further significant aspect of the peninsula's scientific and cultural interest.

The geology of the Yorkshire Dales National Park in northern England largely consists of a sequence of sedimentary rocks of Ordovician to Permian age. The core area of the Yorkshire Dales is formed from a layer-cake of limestones, sandstones and mudstones laid down during the Carboniferous period. It is noted for its karst landscape which includes extensive areas of limestone pavement and large numbers of caves including Britain's longest cave network.

The geology of the Peak District National Park in England is dominated by a thick succession of faulted and folded sedimentary rocks of Carboniferous age. The Peak District is often divided into a southerly White Peak where Carboniferous Limestone outcrops and a northerly Dark Peak where the overlying succession of sandstones and mudstones dominate the landscape. The scarp and dip slope landscape which characterises the Dark Peak also extends along the eastern and western margins of the park. Although older rocks are present at depth, the oldest rocks which are to be found at the surface in the national park are dolomitic limestones of the Woo Dale Limestone Formation seen where Woo Dale enters Wye Dale east of Buxton.

The geology of Pembrokeshire in Wales inevitably includes the geology of the Pembrokeshire Coast National Park which extends around the larger part of the county's coastline and where the majority of rock outcrops are to be seen. Pembrokeshire's bedrock geology is largely formed from a sequence of sedimentary and igneous rocks originating during the late Precambrian and the Palaeozoic era, namely the Ediacaran, Cambrian, Ordovician, Silurian, Devonian and Carboniferous periods, i.e. between 635 and 299 Ma. The older rocks in the north of the county display patterns of faulting and folding associated with the Caledonian Orogeny. On the other hand, the late Palaeozoic rocks to the south owe their fold patterns and deformation to the later Variscan Orogeny.

References

  1. British Geological Survey 1:625,000 scale geological map Bedrock Geology UK North 5th Edn. NERC 2007
  2. 1 2 3 4 5 6 7 Lawrence, D.J.D.; Vye, C.L.; Young, B. (2004). Durham Geodiversity Audit (PDF) (Report). Durham County Council. Retrieved 11 October 2023.
  3. DGA p23
  4. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) p18
  5. "BGS Lexicon of Named Rock Units - Result Details". webapps.bgs.ac.uk.
  6. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) p152
  7. DGA p26
  8. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) pp124-125
  9. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) pp238-254
  10. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) p
  11. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) p162
  12. "National Character Area profiles: data for local decision making". GOV.UK.
  13. King, A. 2012 Strategic Stone Study: a building stone study of County Durham, Tyne and Wear & Cleveland English Heritage
  14. http://www.northpennines.org.uk/Lists/DocumentLibrary/Attachments/175//GeodiversityAudit.pdf Archived 4 March 2016 at the Wayback Machine North Pennines AONB geodiversity audit PDF
  15. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) pp200-205
  16. BGS p184
  17. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) p154
  18. Stone et al 2010 British Regional Geology: Northern England (5th edition) (Keyworth, Nottingham: British Geological Survey) pp226-227
  19. British Geological Survey 1:625,000 scale geological map Quaternary Map of the United Kingdom South 1st Edn. 1977
  20. "Archived copy" (PDF). Archived from the original (PDF) on 4 March 2016. Retrieved 1 August 2013.{{cite web}}: CS1 maint: archived copy as title (link)
  21. "Welcome to the Limestone Landscapes Partnership". Archived from the original on 1 November 2013. Retrieved 1 August 2013.
  22. "Archived copy" (PDF). Archived from the original (PDF) on 3 September 2013. Retrieved 1 August 2013.{{cite web}}: CS1 maint: archived copy as title (link)
  23. http://www.northpennines.org.uk/Pages/Europeanandglobalgeopark.aspx Archived 2012-04-08 at the Wayback Machine Geopark website