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Geoconservation Research
2021, Volume 4 / Issue 1 / pages(144-157)
European UNESCO Geoparks: Original Article
1 Black Country UNESCO Global Geopark, Dudley Museum at the Archives, Tipton Road, Dudley, West Mid- lands, DY1 4SQ, UK.
2 Natural England, Unex House, Peterborough, PE11NG, UK.
Colin D. Prosser Natural England, Unex House, Peterborough, PE11NG, UK
Email: colin.prosser@naturalengland.
org.uk
Abstract
Article information | |
Received: 2021-02-05 Accepted: 2021-05-29 DOI: 10.30486/GCR.2021.1922756.1084 How to cite: Worton G, Prosser C & Larwood J (2021). Palaeontological and geological highlights of The Black Coun- try UNESCO Global Geopark. Geoconservation Research.4(1): 144-157. doi: 10.30486/gcr.2021.1922756.1084 Geoconservation Research e-ISSN: 2588-7343 p-ISSN: 2645-4661 © Author(s) 2020, this article is published with open access at http://gcr.khuisf.ac.ir |
The Black Country UNESCO Global Geopark (Prosser 2020; Worton & Prosser 2021) https:// blackcountrygeopark.dudley.gov.uk/bcg/) lies im- mediately to the west of the city of Birmingham in central England, UK (Fig. 1). It is 356 km2 with a population of 1.1 million people and is underlain by one of the earliest and most important coalfields and industrial areas in the UK. Jukes (1859) noted that the South Staffordshire (Black Country) coal- field is unique amongst British Coalfields because of its concentration of minerals in its condensed sequences, whilst Elihu Burritt, the American Consul in Birmingham, wrote “The Black Country
It is this industrial activity, with its associated excavation and mineral exploitation, including the construction of hundreds of miles of canals,
which exposed more rock layers and opened the ground to the burgeoning science of geology. For example, Murchison visited the area during the 1830s, at a time of the most intensive mining and industrialization of the Black Country and was able to access fresh exposures and consult widely with the mining community to gain a systematic understanding of the local geology. His magnum opus, ‘The Silurian System’ (Murchison 1839), established a framework for the subdivision of Silurian stratigraphy and draws heavily on mate- rial collected from the mined limestone caverns of Dudley. A detailed understanding of the area’s complex Late Carboniferous geology was also be- ing established at this time, with plant collections from Carboniferous coal mines, spoil heaps and iron workings permitting correlation within and between coalfields of the 1850s (Jukes 1859; Kid- ston 1914; Kidston 1923-25). A desire to conserve this resource through protecting what remains of these industrial sites and the collections they have produced led to the Black Country playing a leading role and serving as a testing ground for geoconservation (Box & Cutler 1988; Prosser & Larwood 2008; Worton 2008). This combination of pioneering work in both geoscience and geo- conservation was important in gaining UNESCO Global Geopark status.
A substantial volume of geological literature, par- ticularly a suite of geological memoirs produced by the British Geological Survey (BGS), trace the understanding of the geology of the Black Coun- try and its immediate surroundings over time. The earliest detailed collation of information was the survey by Jukes (1859), with the most significant recent revisions being Powell et al. (1992), who provided a geological context for planning and de- velopment, and Waters et al. (2013).
The central section of the Black Country (Fig. 1) comprises folded and faulted Silurian and Car- boniferous sedimentary rocks with rich and beau- tifully preserved fossil fauna and flora. This inner
Figure 1. Black Country UNESCO Global Geopark, showing its underlying geology and location.
core is flanked by downfaulted younger terrestri- al Permian and Triassic red beds to the east and west and overlain by a thin cover of Quaternary deposits (cut by deeper glacial channels) across the northern part of the Black Country. The whole area is underlain at depth by a rigid crustal block (known as the Midlands Microcraton) which pre- vented intense deformation of these strata during two orogenic episodes and restricted basin subsid- ence. The resulting condensed sequences in effect ‘concentrated’ the paleontological content of the strata and promoted conditions in which excep- tional preservation could occur.
The abundance and proximity of economically important mineral resources established the Black Country as the earliest industrialized conurbation, and access to well exposed geological sequences played a significant role in the development and application of geoscience. The world’s oldest ‘true’ geological map with a scale, geographic features and named mineral horizons was created
here in 1665 (Dudley 1665), the oldest geophysical investigations (density logging) took place here in the early 1700s (Bellers & Hauksbee 1710) and one of the world’s earliest recording seismographs was manufactured here (in West Bromwich) in 1913 (Musson 2013). Connecting canals, mining invention and innovation, and the consequent ex- posure of surface to deep strata led to paleonto- logical discoveries. In turn this led to a reputation as a source of spectacular fossils and a major area for geological research during the 1830s, leading to the naming of the Silurian Period of geological time (Murchison 1839).
The oldest exposed strata of the Black Country are folded inliers of Silurian marine carbonate dom- inated sedimentary rocks forming the prominent Castle, Wren’s Nest and Sedgley Hills in Dudley and the landscape around Walsall (Butler 1939). The Silurian exposures contain complete uninter- rupted Much Wenlock Limestone Formation and
Lower Ludlow successions deposited in a shal- low marine shelf sea (Aldridge et al. 2000; Ray & Thomas 2007). Lithological, sedimentologi- cal, geochemical and paleontological evidence indicates a mid-inner platform position on the eastern margin of a subduction zone with distal island arc volcanism (the closing Iapetus Ocean) (Ratcliffe & Thomas 1999; Ray et al. 2011). The depositional setting is interpreted as a back-reef lagoon with the development of patch reefs and shelly shoals (Ray et al. 2010). Of particular rel- evance to the exceptional preservation of lager- stätten in these sequences are numerous bentonite clays representing eruptive phases of the island
arc volcanoes. The bentonites rapidly buried and preserved in situ seafloor community assemblages in life position including microfaunas that are cur- rently being studied (for example, Jarochowska et al. 2018) and have also yielded isotope dated zircons (Cramer et al. 2012). Paleontological ev- idence indicates a tropical climate, shallow water (dominantly within the photic zone environment, with water depths varying between slightly above fair weather wave-base and slightly below storm wave-base) during the main Wenlock limestone formation with preceding and succeeding times of prevailing deeper water conditions.
Figure 2. Wren’s Nest National Nature Reserve and Geosite, geotrail locations. A) trench excavated in 1977 pro- viding a dip section through the Nodular Member of the Much Wenlock Limestone Formation on the eastern side of the Wren’s Nest Hill. B) Landscape specialists at the quarry viewpoint: the surrounding Wren’s Nest housing estate (on Coal Measures) is seen in the distance, in the middle ground is a prominent reef bioherm of the Nodular Member and the remnants of the elongate quarry in the Lower Quarried Limestone Member. C) Geoconservation training at the viewing platform for the Seven Sisters caverns. The fence encloses unstable ground (due to mining subsidence) where remaining pillars of the Seven Sisters caverns are visible. Here limestone was mined following the steeply dipping beds into the hillside, the caverns have been temporarily infilled with aggregate to prevent collapse.
The Much Wenlock Limestone Formation of the Black Country is classically exposed in the Wren’s Nest National Nature Reserve (Fig. 2) in the heart of Dudley (Cutler et al. 1990) where more than 600 marine invertebrate macrofossil species be- longing to 27 different taxa are found (Aldridge 2000; Reid & Gryckiewicz 1995). A selection of these are illustrated in Figure 3. Over 65% of the Wenlock species illustrated in ‘The Silurian Sys-
tem’ (Murchison 1839) are from the Geopark. Such was the fame and enthusiasm for these fos- sils that the trilobite Calymene blumenbachii (Fig. 3A) became the mascot of the limestone miners and was adopted into Dudley’s coat of arms (Mi- kulic & Kluessendorf 2007). Among scientists of the day, it earned the title the Dudley Fossil (Par- kinson 1804-1811) and is now amiably referred to by local people as the Dudley Bug.
Figure 3. Silurian fossils from the Much Wenlock Limestone Formation of the Wren’s Nest NNR and Geosite.
A) Calymene blumenbachii (Brongniart 1822), the ‘Dudley Bug’. B) Halysites catenularius (Linneaus 1822). C) Much Wenlock Limestone death assemblage. D) Gissocrinus goniodactylus (Phillips 1839). Scale bar = 5cm.
and lakes at, or slightly north of, the equator in tropical climates. This gently subsiding environ- ment was dominated by rhythmically repeating mudstones, siltstones, and sandstones with abun- dant economic minerals: fireclays, clays, iron- stones, and the coals of the South Staffordshire Coalfield (Beasley 1987; Cleal & Thomas 1996). Saltwells National Nature Reserve (Fig. 4), in
Dudley, encompasses the characteristic strata of the Upper Carboniferous (Jukes 1859; White- head & Eastwood 1927; Cleal & Thomas 1996): cross-bedded river sandstone channels, siltstones, clays (a source of clay for Royal Doulton sanitary- ware), and coal seams, including the still exposed
‘Heathen’ (Fig. 4D) and formerly the Thick Coal – a 12 m seam and the most productive of the In- dustrial Revolution. Carboniferous strata here are unconformable on Upper Silurian mudstones (Fig 4B) that have a diverse Ludlow marine fauna in- cluding fossils of early fish (Aldridge et al. 2000).
Figure 4. Saltwells National Nature Reserve and Geosite. A) Doulton’s Claypit, galvanized steel sculptural inter- pretation of the Carboniferous dragonfly Meganeura (artist Luke Perry) resting on Coal Measures river channel sandstone. B) Brewin’s Canal Cutting examining Silurian – Carboniferous unconformity (arrow), the canal (con- necting with regional and national canal networks) was used to transport coal and clay from Saltwells. C) Cleaning Silurian Ludlow beds with portable high pressure hose. D) General view of Doulton’s Claypit showing alternating sandstone, shale and clay. The Heathen coal seam (arrowed) is visible in the main face.
Occasionally, conditions in these Carboniferous swamps produced exceptional preservation of terrestrial fossils (Fig. 5). Near Wolverhampton, siderite nodules in the Coseley lagerstätte (Fig. 5B) preserve plant and insect faunas in spectacular de-
tail (Braznell 2005). Particularly significant are its trigonotarbid spider-mites (Garwood et al. 2009), other insects, arthropod and plant fauna and flora which provide a very useful comparator to the Ma- zon Creek deposits of the USA (Pacyna & Zdebska
2012). These fossils, now in museum collections including Dudley Museum at the Archives and the Lapworth Museum (Birmingham), were subject to collaborative international research including the application of new investigative x-ray microtopog- raphy techniques (e.g., Garwood & Sutton 2010; Garwood et al. 2009).
The only evidence of Carboniferous extrusive igneous activity occurs in the Etruria Formation at Kingswinford in the Barrow Hill and Tansey Green Clay Pit, where 10 m of gray-green volca- nic ash and ejecta occur (Stephenson et al. 2003). Here, hydrothermal stockworks of alteration and steam eruption injected veins have been dated to 307Ma. These deposits preserve in anatomical detail early conifers in life position (Galtier et al. 1992; Glover et al. 1993). This site is also known as the ‘Dudley Volcano’ and the local communi- ty’s tenants and resident’s association has adopted the volcano as its logo.
With the formation of Pangea, arid climates dom- inated the Permo-Triassic environments of the Black Country. Exposures include red breccias, conglomerates, and aeolian sandstones, whilst alluvial clays and sandstones were deposited by major river systems flowing northwards across the region. Northern and eastern parts of the Geopark exhibit Quaternary glacial tills, fluvial outwash and river deposits, periglacial solifluction and mass movement. Glacial advance and retreat over the last 400,000 years have influenced the evolu- tion of modern river systems and shaped today’s landscape. For example, Norton Covert, in the ex- treme southwest of the Geopark, exposes Deven- sian outwash gravels overlying Permo-Triassic alluvial Wildmoor Sandstone Formation (Black Country Geological Society 2008).
The Black Country became a UNESCO Global Geopark in July 2020 with 44 Geosites (https:// blackcountrygeopark.dudley.gov.uk/sites-to-see/)
identified at the time of joining. Geological ex- posures within the Geopark are dominantly the remnants of mining, quarrying and engineering endeavors. It is the geoheritage accessible at these Geosites, their exceptional paleontology and pa- leontological collections, and the links to local geology, its industrial exploitation and local com- munities that provides the narrative of the Black Country UNESCO Global Geopark.
Geoconservation: There is a long history of geo- conservation within the Black Country and the practice of conserving, improving, interpreting, and providing access to geological features is em- bedded in the policy and practice of the partners in the Geopark (Worton 2008; Prosser & Lar- wood 2008). This is in part due to the scientific significance of the geological features but also the challenge of conserving them within a rapidly de- veloping urban setting (Bennett et al. 1996). The process of urban renewal creates opportunities but also presents potential for loss and damage of geological features to new development. As in most urban areas, geosites are subjected to heavy recreational use and are sometimes the victim of vandalism and illegal waste tipping. Further, oc- casional cases of irresponsible fossil collecting, in a setting where it is not practical to restrict access to geological features, poses further challenges. These challenges have necessitated innovative and often successful attempts to engage and in- volve local communities in understanding and helping to conserve geosites, rather than attempt- ing to exclude them from what are often publicly accessible green spaces (Worton 2008; Prosser & Larwood 2008; Worton & Gillard 2013).
Nationally and internationally important sites have been assessed and identified through the Great Britain wide Geological Conservation Re- view (Ellis et al. 1996) and are here legally pro- tected through designation as nine Sites of Special Scientific Interest (SSSIs). Two of these SSSIs, having exceptional scientific importance, and wide scope for day-to-day management, interpre-
tation and public access, have also been declared as National Nature Reserves (https://www.gov. uk/government/collections/national-nature-re- serves-in-england); the Wren’s Nest (Fig. 2) in 1956 (Prosser & Larwood 2008) and Saltwells (Fig. 4) in 2020 (Larwood 2020). They have per- manent wardens managing the geological fea- tures, volunteer groups that assist them, and are extensively used by local community and schools as well as by geologists. Both are regularly used to demonstrate good practice in geological conserva- tion (Fig. 2C), interpretation and community en- gagement (through training courses, conferences, field excursions, guided walks and peer reviewed papers). For example, the Wren’s Nest has been the subject of pioneering work managing geolog- ical features (Prosser & Larwood 2008) and en- gaging with the local community (Worton & Gil- lard 2013) in a populated urban area and in a place subject to active ground subsidence. This has in- cluded one of the first self-guided geological trails (Warwick et al. 1967), trialing approaches to the management of fossil collecting, the cutting of a new geological section to replace a long-standing section which became too dangerous to access be- cause of ground subsidence, geologically themed drama performances to engage with local youths, extensive use of volunteers in building paths and keeping geological features free of vegetation and scree, the use of vandal-resistant signage and in- terpretation, production of a fossil themed beer, ‘Trilobitter’, to raise awareness of the local ge- ology and paleontology, and the long-term use of fixed point monitoring of geological features with nearly 40 years of data (Larwood 2002; Prosser & Larwood 2008; Roworth & Larwood 2004).
During the 1970s and 1980s, in response to devel- opment pressure affecting many locally important sites, an audit of geological features, led by the Black Country Geological Society (BCGS), was carried out. This audit generated a list of Local Geological Sites (Defra 2006; Worton 2008) rec- ognized within the Black Country planning frame- work, which must be considered when assessing
any development proposals. Recognition of these sites in the local planning system has also reduced the chance of them being accidentally damaged by developers ignorant of their importance or loca- tion.
Whilst many threats to geosites in the Geopark are anthropogenic, others are more natural in or- igin. Unchecked growth of vegetation on some sites requires regular cutting back and community groups, sometimes coordinated by local warden- ing teams, have engaged in this work. The Black Country Geological Society, inaugurated in 1975, has geoconservation at its heart, and every year organizes work parties to clear and maintain rock faces in geosites.
In addition to site-based conservation, the Geopark Headquarters (Dudley Museum at the Archives, and Geosite) in Dudley (Worton 2019) includes nationally significant collections of local paleon- tological material, including Carboniferous plant and invertebrate fossils (Fig. 5) and most nota- bly Silurian trilobites, crinoids and other marine invertebrates (Fig. 3), amassed over the last 160 years. This collection contains several type and figured specimens including the specimen of Eu- calyptocrinus crassus figured in Murchison’s ‘Si- lurian System’ in 1839.
National planning policy guidance in England (Na- tional Planning Policy Framework, 2019) requires local authorities to protect sites of geological val- ue, ‘… in a manner commensurate with their statu- tory status or identified quality in the development plan’. In the Black Country, however, additional Supplementary Planning Documents have been produced. For example, the Dudley Borough De- velopment Strategy Development Plan Document (adopted 2016) recognizes the importance of geo- logical features within the context of sustainable development. At a strategic level the Black Coun- try Core Strategy (https://blackcountryplan.dud- ley.gov.uk/t1/p2/) includes Policy ENV1 ‘Nature Conservation’, which recognizes the importance
Figure 5. Carboniferous fossils, Coal Measures siderite nodules. A) Calamites suckowi (Brongniart 1822). B)
Apthoroblattina sp. from Coseley Lagerstätten; C - Neuropteris gigantea (Sternberg 1825). Scale bar = 5cm.
of geological features by stating that: ‘...Devel- opment within the Black Country will safeguard nature conservation, inside and outside its bound- aries by ensuring that: Locally designated nature conservation sites (Sites of Local Importance for Nature Conservation), important habitats and geo- logical features are protected from development proposals which could negatively impact upon them.....’. This long-term plan is currently being revised and will become ‘The Black Country Plan’ within the next few years. This is a significant step forward for the protection and profile of the Black Country’s geodiversity as it will contain specific policy for the UNESCO Global Geopark. Policies currently under consideration for inclusion spe- cifically refer to geodiversity and the UNESCO Global Geopark and require developers to ‘seek to make a positive contribution to the protection and enhancement of the geodiversity’ and specifically to the nominated Geosites within it.
cation and informal life-long learning welcoming researchers, students, and community groups en- riching learning and providing inspirational places and experiences for all. Dudley was first visited by the Geologists’ Association in 1863 and it was noted then the ‘…several advantages and oppor- tunities it [Dudley] afforded for study, to both the early and advanced student, of several of the great and characteristic phenomena recognised as causes, effects, and agencies by geological sci- ence’ (Geologists’ Association 1863). In 1898 the Geologists’ Association returned and record trav- elling on the underground canal between Castle Hill and the Wren’s Nest Hill in Dudley and being entertained by Professor Lapworth in the candlelit limestone caverns (Watts 1898). Most recently, in October 2018, the area jointly hosted the Ge- ologists’ Association annual conference entitled ‘The Geology of Mordor’ drawing on the cultural connections with the industrial landscape and its reflections in popular literature such as JRR Tolk- ien’s ‘Lord Of The Rings’.
There has been a particular focus in engaging young people in the Geopark’s geoheritage. For example, the ‘Waves’ project that linked schools, geosites and museums through fossil collections, the innovative ‘Wrosne’ theatre performance de- livered by young people from the communities surrounding the Wren’s Nest NNR, and the muse- um’s GeoTeam, student volunteers (geology stu- dents from local schools and universities) (Worton & Gillard 2013). The GeoTeam supports the work of the Geopark helping document collections, un- dertake field logging and sampling and support a range of geoconservation activities, as well as growing the confidence, knowledge and experi- ence of the GeoTeam volunteers. More recently the Geopark Headquarters (and many of the out- door Geosites) have provided the resources for 45 Day Apprenticeships as well as support to profes- sional learning and Continuing Professional De- velopment (CPD).
and ‘Silurian Mews’.
The area’s prominence and importance in global geoscience and industrial history also attract in- ternational groups. The ‘Murchison Symposium’ visited the Black Country in 1989 on the 150th an- niversary of the publication of ‘The Silurian Sys- tem’, the ‘Trilobites and their Relatives’ Confer- ence held field visits here in 2001, and the Silurian Sub-commission visited in 2011. Recent research projects have included international collaboration (Cramer et al. 2012; Jarochowska et al. 2018; Ray et al. 2020).
The development of geotourism in the Black Country is part of an ongoing process of over- all tourism development in the region and the Geopark is written into strategic policies for the visitor economy. There is a strong and develop- ing baseline infrastructure for tourism, with many existing visitor attractions and natural sites linked within the Geopark as a single landscape story. Some improvements in tourism infrastructure are planned for the Geopark, including the Mid- land Metro tramway system between the towns of Wednesbury and Brierley Hill which is currently under construction, adding 18 new stations and improving public transport within the geopark; five stations are on or immediately adjacent to named geosites, including the Geopark Headquar- ters. Interpretation on these stations and onboard this new transport network is currently being de- signed and will be in place when the region hosts the Commonwealth Games in August 2022.
There is huge potential for tourism growth and impacts on education, wellbeing, quality of envi- ronment, inward investment and overall econom- ic performance of the Black Country. Tourism is promoted strongly (see Dudley Metropolitan Bor- ough Council 2019) whilst visitor surveys (The research solution 2020) show a growing audi- ence both in terms of UK and overseas audiences. Geotourism here provides the opportunity to tell geological stories that engage and inspire, attract-
ing visitors (from local to global) and contributing to a new aspect of the tourism economy for the Black Country (Larwood & Worton 2018). This can only lead to a raised profile for the Geopark’s rich geoheritage.
The Black Country UNESCO Global Geopark was welcomed into the Global Geoparks Network in July 2020 as a different very urban territory with an extremely rich geological, paleontological and related cultural heritage in close contact with the local community (Fig. 6). In terms of its geol- ogy and paleontology, research on the microfauna of the Geopark’s Much Wenlock Limestone For- mation is ongoing. This is providing a baseline un- derstanding of the diversity and distribution of mi- crofossils throughout these sequences and will be followed by publications on little-studied groups from these successions such as chitinozoans and
scolecodonts. This research is being led by the Geopark and its volunteers in collaboration with the University of Portsmouth, University of Erlan- gen and the private sector company Neftex. The Geopark is also currently auditing the paleontolo- gy of the Coal Measures sequence from its historic museum collections in order to better understand its faunal and floral diversity. The Geopark’s exist- ing geoconservation experience is being extended through the management program across the net- work of geosites working in collaboration with communities and agencies across the Geopark.
The Black Country UNESCO Global Geopark will enable reconnection of local communities to their shared geological heritage through increasing ac- cess to its geosites, a range of educational and interpretive initiatives, and through new connec- tions with the global Geopark community. For example, existing resources for geosites are be-
Figure 6. Showing the urban character of the Black Country UNESCO Global Geopark and the close proximity of Geosites to the local community. A) Tilted limestones bedding planes of the Wren’s Nest National Nature Reserve seen from Burton Road, Wren’s Nest Estate. B) Looking out from the Wren’s Nest National Nature Reserve across the Wren’s Nest Estate.
ing reviewed and updated, a new visitor center at Saltwells National Nature Reserve is being fitted with new resources for learning, a 45-day appren- ticeship scheme is being planned, familiarization trips for public sector workers and politicians are being scheduled, themed presentations at events and conferences will continue, virtual field excur- sions are being developed for those with accessi- bility challenges, bespoke on-site signage is being installed on key Geosites, updated field guides are being drafted and new online resources are being developed.
We thank the editors and two reviewers for ex- tremely helpful comments and David Evans for redrafting Figure 1.
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