Earth:Wellheim Formation
| Wellheim Formation Stratigraphic range: upper Cenomanian to lower Turonian[1] 98–91 Ma | |
|---|---|
 Siliceous earth quarrying of the Wellheim Formation near Neuburg | |
| Type | Geological formation |
| Unit of | Danubian Cretaceous Group |
| Sub-units | basal marine sandstone, Neuburg Kieselerde Member, Homsand facies[2] |
| Underlies | Upper Freshwater Molasse Formation or Pleistocene loams |
| Overlies | Schutzfels Formation or Upper Jurassic limestone |
| Area | southern Franconian Jura, Upper Bavaria[1] |
| Thickness | up to 130 metres (430 ft) |
| Lithology | |
| Primary | spiculitic silt, fine and medium sands, fine-grained silica (Kieselerde)[1] |
| Other | silicified conglomerate |
| Location | |
| Country | Germany |
| Extent | 200 km2 (77 sq mi) |
| Type section | |
| Named for | Wellheim |
| Named by | B. Niebuhr, T. Pürner, and M. Wilmsen |
| Location | open pit mines near Wellheim, Germany |
| Year defined | 2009 |
| Country | Germany |
The Wellheim Formation is a geological formation in southern Germany deposited during the Cenomanian to earliest Turonian stages of the Upper Cretaceous.
The Formation is subdivided into three member units: unnamed basal marine sandstone, the Neuburg Kieselerde Member, and an upper silicified conglomerate (Homsand facies).[2]
Geographically, this formation is located in the central southernmost part of the Franconian Jura, on the left bank of the Danube, roughly between the towns of Wellheim and Neuburg in Bavaria.
The formation is commercially quarried for siliceous earth, which has a variety of applications.
Stratigraphy
The formation infills karstic voids found in Upper Jurassic limestones. Its upper contact is with either Miocene Upper Freshwater Molasse clays and marls or Pleistocene glacial deposits[3] while the lower contact is with the Jurassic limestones, or the Lower Cretaceous Schutzfels Formation, a terrestrial unit which also infills the karstic terrain.
Depositional Environment
The Wellheim Formation was formed in a quiet water environment[4] by deposition of pelagic sediments into a number of submerged karsts in the ocean floor over several million years.[5] Wilmsen et al (2010) identified the primary sediment composition as sandy and spiculitic sediments, with notably little terrigenous input.[4]
It has since been classified as an Opoka type marine deposit, a term that is primarily used to refer to Upper Cretaceous sponge spicule rich siliceous limestones found in Poland and western Ukraine.[6]
Lüttig (2007) called the scientific view of the formation of the Neuburg Kieselerde Member "contested"[lower-alpha 1][7] however that position has not been supported by subsequent authors.
Fossils
The Wellheim Formation is fossiliferous with the Neuburg Kieselerde Member having one of the most diverse invertebrate assemblages in the Danubian Cretaceous Group.[8] Schneider et al. (2013) mapped fossil yielding localities associated with this member in a rough triangle between Wellheim, Rennertshofen and Neuburg.[9]
Age and correlation
It was deposited between about 93 to 98 million years ago during the Cenomanian, the lowest stage of the Upper Cretaceous.
The index fossil associated with these sediments is Inoceramus crippsi, a wing-shaped (pteriomorph) salt-water bivalve.[10]
Commercial exploitation
Mining of Neuburg Kieselerde Member sediments takes place at an industrial scale around Neuburg an der Donau. The products are marketed under the umbrella term siliceous earth (German: Kieselerde). The sediment is used as a filler material,[11][12][13] an abrasive and polishing medium,[14] a paint and varnish additive[15] and as a nutritional supplement.[16][17]
It is generally composed of silicic acid (80 percent by weight or less) and kaolinite.[18]
In 2015, 55,000 tons of the purified material were produced. This required the open-pit mining of 120,000 tons of raw siliceous earth.[19]
The producer has claimed a non-biogenic, mineral origin for their product,[18] while most other sources assert a biogenic origin for the material.[lower-alpha 2][8] Substances called siliceous earths are usually defined as having a biogenic origin,[20] with material of a similar composition usually being termed diatomaceous earth.
The producer also has repeatedly claimed a unique "one-of-a-kind worldwide" status of their product,[21][22] but Lüttig refuted this in 2007 for the material that is produced, saying that several similar material deposits are known, naming Heiligenhafen Kieselgestein as an example. On the other hand he agreed that the very special formation circumstances could indeed be called unique.[7]
It has historically been used for the production of glass,[23] ceramics[17] and color pigments like ultramarine.
Notes
- ↑ German: "nicht unumstritten",[7] referring to the dissenting view of the sole exploiting company
- ↑ For example, Schneider et al., 2013 have this statement as the first sentence of their article's abstract: "With approximately 100 species, the invertebrate macrofauna of the Neuburg Kieselerde Member of the Wellheim Formation (Bavaria, southern Germany) is probably the most diverse fossil assemblage of the Danubian Cretaceous Group."[8]
References
- ↑ 1.0 1.1 1.2 Niebuhr, Pürner & Wilmsen 2009, pp. 17–19.
- ↑ 2.0 2.1 Schneider et al. 2013, figure 3.
- ↑ Salvador et al. 2016, p. 129.
- ↑ 4.0 4.1 Wilmsen et al. 2010, p. 274.
- ↑ Schneider et al. 2013, pp. 556–557.
- ↑ Machalski & Malchyk 2019, p. 30.
- ↑ 7.0 7.1 7.2 Lüttig 2007, p. 156.
- ↑ 8.0 8.1 8.2 Schneider et al. 2013, abstract.
- ↑ Schneider et al. 2013, figure 1.
- ↑ Schneider et al. 2013, pp. 555–610.
- ↑ Mushack & Bachmann 1996.
- ↑ Heckl & Knör 2011.
- ↑ Schönrock 2008.
- ↑ Stork 2009.
- ↑ Roth, Reiter & Oggermüller 2020.
- ↑ Hoffmann Mineral GmbH 2010.
- ↑ 17.0 17.1 Lüttig 2007.
- ↑ 18.0 18.1 Göske & Kachler 2008, pp. 23–24.
- ↑ Elsner 2016, p. 45.
- ↑ Meyers 1892.
- ↑ Schanz 2016.
- ↑ Baublatt 2019.
- ↑ Römpp 2015.
Sources
- Elsner, Harald (28 January 2016) (in de) (PDF). Quarzrohstoffe in Deutschland. Deutsche Rohstoffagentur. ISBN 9783943566314. https://www.bgr.bund.de/DERA/DE/Downloads/studie-quarz-2016.
- Groteklaes, Michael, ed. "Kieselerde, RD-11-01037". RömppOnline. https://roempp.thieme.de/lexicon/RD-11-01037. Retrieved 2 January 2015.
- Göske, Jürgen; Kachler, Werner (September 2008). "Morphology, Physiochemistry and Phase Analysis of Neuburg Siliceous Earth". Microscopy and Analysis (Weinheim: Wiley-VCH GmbH) September 2008: 23–24. https://www.hoffmann-mineral.com/en/documents/general-documents/publications/morphology-physicochemistry-and-phase-analysis-of-neuburg-siliceous-earth-%28microscopy-and-analysis-9-2008%29.pdf.
- Heckl, Siegfried; Knör, Nicole (2011). "Better filling of polyamides". Kunststoffe International (Munich: Carl Hanser Verlag) 2/2011: 70–73. ISSN 1862-4243. https://www.hoffmann-mineral.com/en/documents/general-documents/publications/better-filling-of-polyamides-%28kunststoffe-international-2-2011%29.pdf.
- Hoffmann Mineral GmbH (30 April 2010), "Aktisil", DPMAregister (German Patent and Trade Mark Office) (1056011), https://register.dpma.de/DPMAregister/marke/registerIR?AKZ=1056011, retrieved 16 August 2021
- "Kieselsäuresalze - Kieselschiefer". Meyers Konversationslexikon. Leipzig; Wien: Verlag des Bibliographischen Instituts. 1885–1892. http://www.retrobibliothek.de/retrobib/seite.html?id=109312.
- Lüttig, Gerd (2007). "Kieselerde ist nicht gleich Kieselgur - Naturwissenschaftliche Anmerkungen zu Heilerde-Präparaten" (in de). Erfahrungsheilkunde 56 (3): 154–161. doi:10.1055/s-2007-968058. ISSN 1439-4294. Archived from the original on 16 August 2021. https://web.archive.org/web/20210816030201/https://www.hoffmann-mineral.de/de/dokumente/allgemeine-dokumente/veroeffentlichungen/kieselerde-ist-nicht-gleich-kieselgur-(ehk-56-2007).pdf.
- Machalski, M.; Malchyk, O. (2019). "Relative bathymetric position of opoka and chalk in the Late Cretaceous European Basin". Cretaceous Research 102: 30–36. doi:10.1016/j.cretres.2019.05.007. https://www.sciencedirect.com/science/article/pii/S0195667119300291.
- Mushack, R.; Bachmann, W. (1996). "Neuburger Kieselerde: natürliche, funktionelle Füllstoffe" (in de). GAK: Gummi, Fasern, Kunststoffe; Fachmagazin für die Polymerindustrie (Ratingen: Gupta) 49 (8): 620–629. ISSN 0176-1625.
- Niebuhr, B.; Pürner, T.; Wilmsen, M. (2009). "Lithostratigraphie der außeralpinen Kreide Bayerns." (in de). Schriftenreihe der Deutschen Gesellschaft für Geowissenschaften (Stuttgart, Germany: Schweizerbart Science Publishers) 65: 7–58. https://www.schweizerbart.de/publications/detail/isbn/9783510492114/Litho_und_Biostratigraphie_der_aueralpinen_Kreide_von_Bayern.
- Roth, Meinhart; Reiter, Susanne; Oggermüller, Hubert (October 2020). "Neuburg Siliceous Earth as a functional extender for high performance road marking paints". Asia Pacific Coatings Journal (Dubai: dmg events) October 2020: 45–47. ISSN 1468-1412. https://www.hoffmann-mineral.com/en/documents/general-documents/publications/nse-in-road-marking-paints-apcj-october2020.pdf.
- Salvador, R. B.; Prieto, J.; Mayr, C.; Rasser, M. W. (2016). "New gastropod assemblages from the Early/Middle Miocene of Riedensheim and Adelschlag-Fasanerie, southern Germany". Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 279 (2): 127–154. doi:10.1127/njgpa/2016/0546.
- Schanz, Sebastian (1 July 2016). "Neuburg: Eine weltweit einzigartige Ressource" (in de). Ingolstadt: Donaukurier. https://www.donaukurier.de/lokales/neuburg/art1763,3237755.
- Schneider, S.; Jaeger, M.; Kroh, A.; Mitterer, A.; Niebuhr, B.; Vodrážka, R.; Wilmsen, M; Wood, C. et al. (2013). "Silicified sea life–Macrofauna and palaeoecology of the Neuburg Kieselerde Member (Cenomanian to Lower Turonian Wellheim Formation, Bavaria, southern Germany)". Acta Geologica Polonica 63 (4): 555–610. doi:10.2478/agp-2013-0025. https://geojournals.pgi.gov.pl/agp/article/view/10370/8881.
- Schönrock, Dirk (2008) (in de). Neuburger Kieselerde: Gewinnung, Veredelung, Anwendungen als funktioneller Füllstoff [Hoffmann Mineral]. Die Bibliothek der Technik. 308. Landsberg: Verlag Moderne Industrie. ISBN 9783937889771.
- Stork, Stefanie (25 August 2009). "Von der Kieselerde zum Poliermittel" (in de). Augsburger Allgemeine. https://www.augsburger-allgemeine.de/neuburg/Von-der-Kieselerde-zum-Poliermittel-id6357946.html.
- Wilmsen, Markus; Niebuhr, Birgit (2010). "On the age of the Upper Cretaceous transgression between Regensburg and Neuburg an der Donau". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen 256 (3): 267–278. doi:10.1127/0077-7749/2010/0051.
- "Hoffmann Mineral baut Kieselerde ab – ein weltweit einzigartiges Vorkommen" (in de). Zeppelin Baumaschinen GmbH. 27 August 2019. https://www.baublatt.de/startseite/hoffmann-mineral-baut-kieselerde-ab-ein-weltweit-einzigartiges-vorkommen/. Retrieved 17 June 2021.
Further reading
- Glossary of Geology (5th ed.). Alexandria, Virginia: American Geological Institute. 2011. ISBN 978-0922152896. https://app.knovel.com/web/toc.v/cid:kpGGE00002/viewerType:toc/.
- Stokes, W.L.; Varnes, V.J. (1955). Glossary of Selected Geologic Terms with special reference to their use in engineering. Denver, Colorado: Colorado Scientific Society. p. 165.
- Grout, F.F. (1932). Petrography and petrology, a textbook. New York, New York: McGraw-Hill Book Co. p. 522.
- "The New IMA List of Minerals". International Mineralogical Association. 2021. http://cnmnc.main.jp/IMA_Master_List_%282021-05%29.pdf. Retrieved 28 June 2021.
- "Schönheitsmittel Kieselerde unter Verdacht" (in de), plusminus [de] (ARD), 6 November 2007, http://www.presseportal.de/pm/6561/1078968/ard-magazin-plusminus-und-ndr-info-schoenheitsmittel-kieselerde-unter-verdacht
- Göske, Jürgen (21 January 2008), Summary based on the expertise No. 7042729: Optoelectronic, Physical-Chemical and Phase-Analytical Investigations on Neuburg Siliceous Earth, Hoffmann Mineral GmbH, https://www.hoffmann-mineral.com/en/documents/general-documents/publications/expertise-on-neuburg-siliceous-earth-%28goeske-2008%29.pdf
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