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Facies

, Volume 53, Issue 4, pp 615–623 | Cite as

Paleoecology of Pennsylvanian phylloid algal buildups in south Guizhou, China

  • Gong Enpu
  • Elias SamankassouEmail author
  • Guan Changqing
  • Zhang Yongli
  • Sun Baoliang
Original Article

Abstract

Pennsylvanian phylloid algal reefs are widespread and well exposed in south Guizhou, China. Here we report on reefs ranging from 2 to 8 m thickness and 30–50 m lateral extension. Algae, the main components, display a wide spectrum of growth forms, but are commonly cyathiform (cup-shaped) and leaf-like (undulate plates). The algal reef facies is dominated by boundstone. Algal thalli form a dense carpet whose framework pores are filled with marine cement and peloidal micrite. The peloidal matrix is dense, partly laminated or clotted with irregular surfaces and often gravity defying. Algal reefs in Guizhou differ from examples reported to date by the high biodiversity of organisms other than phylloids: e.g., the intergrowth of algae with corals (some of which are twice the size of algal thalli) and numerous large brachiopods. This contrasts to previous views that phylloid algal “meadows” dominated the actual seafloor, excluding other biota. Also, the pervasive marine cements (up to 50%) including botryoidal cement are noteworthy. Algal reefs developed at platform margins, a depositional environment similar to that of modern Halimeda mounds in Java, Australia and off Bahamas, and to that of time-equivalent examples reported from the Canadian Arctic Archipelago. Whereas nutrients appear decisive in the growth of Halimeda reefs, algal reefs reported herein seemingly grew under conditions of low nutrient levels. Overall, algal reefs in Guizhou challenge previous views on growth forms, diversity patterns, and depositional environments and add to the spectrum of these partly puzzling biogenic structures.

Keywords

Phylloid algae Buildups Paleoecology Guizhou Pennsylvanian 

Notes

Acknowledgements

We thankfully acknowledge the final support of the National Science Foundation of China (Grant No. 40572014) to Gong Enpu and the Swiss National Science Foundation (Project 200021-107505) to Elias Samankassou. We thank two anonymous journal reviewers for comments and A. Freiwald for editorial advice which improved the initial draft of the manuscript.

References

  1. Baars DL (1992) Kansaphyllum, a new Late Pennsylvanian phylloid algal genus. J Paleontol 66:697–701Google Scholar
  2. Baars DL, Torres AM (1991) Late Paleozoic phylloid algae: a pragmatic review. Palaios 6:513–515CrossRefGoogle Scholar
  3. Beauchamp B, Davies GR, Nassichuk WW (1989) Upper Carboniferous to Lower Permian Palaeoaplysina-phylloid algal buildups, Canadian Arctic Archipelago. Canad Soc Petrol Geol Mem 13:590–599Google Scholar
  4. Chisholm JRM, Kelley R (2001) Marine ecology: worms start the reef-building process. Nature 409:152CrossRefGoogle Scholar
  5. Crowley DJ (1969) Algal-bank complex in Wyandotte Limestone (Late Pennsylvanian) in eastern Kansas. Kansas Geol Surv Bull 198:1–52Google Scholar
  6. Davies GR (1977) Former magnesian calcite and aragonite submarine cements in Upper Paleozoic reefs of the Canadian Arctic: a summary. Geology 5:11–15CrossRefGoogle Scholar
  7. Davies PJ, Braga JC, Lund M, Webster JM (2004) Holocene deep water algal buildups on the Eastern Australian Shelf. Palaios 19:598–609Google Scholar
  8. Davies GR, Richards BC, Beauchamp B, Nassichuk WW (1989) Carboniferous and Permian reefs in Canada and adjacent areas. Canad Soc Petrol Geol Mem 13:565–574Google Scholar
  9. Drew EA, Abel KM (1988) Studies on Halimeda. Coral Reefs 6:195–205CrossRefGoogle Scholar
  10. Doherty PD, Soreghan GS, Castagna JP (2002) Outcrop-based reservoir characterization: a composite phylloid-algal mound, western Orogrande Basin (New Mexico). AAPG Bull 86:779–795Google Scholar
  11. Fan J, Rigby JK (1994) Upper Carboniferous phylloid algal mounds in Southern Guizhou, China. Brigham Young Univ Geol Stud 40:17–24Google Scholar
  12. Feng Z, Yang Y, Bao Z, Jin Z, Zhang H, Wu X, Qi D (1998) Lithofacies paleogeography of Carboniferous in South China (in Chinese with English abstract). Geological Publishing House, Beijing, 119 ppGoogle Scholar
  13. Flügel E (1979) Paleoecology and microfacies of Permian, Triassic and Jurassic algal communities of platform and reef carbonates from the Alps. Bull Centres Recherch Explor-Product Elf-Aquitaine 3:569–587Google Scholar
  14. Forsythe GTW (2003) A new synthesis of Permo-Carboniferous phylloid algal reef ecology. SEPM Spec Publ 78:171–188Google Scholar
  15. Forsythe GTW, Wood R, Dickson JAD (2002) Mass spawning in ancient reef communities: evidence from Late Paleozoic phylloid algae. Palaios 17:615–621Google Scholar
  16. Freile D, Milliman JD, Hillis L (1995) Leeward bank margin Halimeda meadows and draperies and their sedimentary importance on the western Great Bahama Bank slope. Coral Reefs 14:27–33CrossRefGoogle Scholar
  17. GGMRB (Guizhou Geology, Mineral Resource Bureau) (1987) The Guizhou regional geology (in Chinese with English abstract). Geology Publishing House, Beijing, 698 ppGoogle Scholar
  18. Gray RS (1967) Cache field: a Pennsylvanian algal reservoir in southwestern Colorado. AAPG Bull 51:1959–1978CrossRefGoogle Scholar
  19. Hay ME (1997) Calcified seaweeds on coral reefs: complex defenses, trophic relationships, and value as habitats. Proceedings of the 8th International Coral Reef Symposium, Panamy City, Panama, June 1996, vol I, pp 713–718Google Scholar
  20. Heckel PH (1986) Sea-level curve for Pennsylvanian eustatic marine transgressive-regressive depositional cycles along midcontinent outcrop belt, North America. Geology 14:330–334CrossRefGoogle Scholar
  21. Heckel PH (1994) Evaluation of evidence for glacial eustatic control over marine Pennsylvanian cyclothems in North America and consideration of possible tectonic effects. Concepts Sedimentol Paleontol 4:65–87Google Scholar
  22. Heckel PH, Cocke JM (1969) Phylloid algal-mound complexes in outcropping Upper Pennsylvanian rocks of Mid-Continent. AAPG Bull 53:1058–1074CrossRefGoogle Scholar
  23. James NP, Ginsburg RN (1979) The seaward margin of Belize barrier and atoll reefs. Special Publication, International Association of Sedimentologists, Surrey, UK, vol 3, 191 ppGoogle Scholar
  24. James NP, Ginsburg RN, Marszalek DS, Choquette PW (1976) Facies and fabric specificity of early subsea cements in shallow Belize (British Honduras) reefs. J Sedimentary Petrol 46:523–544Google Scholar
  25. Joachimski MM, von Bitter PH, Buggisch W (2006) Constraints on Pennsylvanian glacioeustatic sea-level changes using oxygen isotopes of conodont apatite. Geology 34:277–280CrossRefGoogle Scholar
  26. Kirkland BL, Moore CH Jr, Dickson JAD (1993) Well-preserved, aragonitic phylloid algae (Eugonophyllum, Udoteaceae) from the Pennsylvanian Holder Formation, Sacramento Mountains, New Mexico. Palaios 8:111–120CrossRefGoogle Scholar
  27. Konishi K, Wray JL (1961) Eugonophyllum, a new Pennsylvanian and Permian algal genus. J Paleontol 35:659–666Google Scholar
  28. Marshall JF, Davies PJ (1988) Halimeda bioherms of the northern Great Barrier Reef. Coral Reefs 6:139–148CrossRefGoogle Scholar
  29. Martin J, Braga J, Riding R (1997) Late Miocene Halimeda alga-microbial segment reefs in the marginal Mediterranean Sorbas Basin, Spain. Sedimentology 44:441–456CrossRefGoogle Scholar
  30. Paul VJ (1997) Secondary metabolites and calcium carbonate as defenses of calcareous algae on coral reefs. In: Proceedings of the 8th International Coral Reef Symposium, Panama City, Panama, June 1996, vol I, pp 707–712Google Scholar
  31. Pol JC (1985) Sedimentation of an Upper Pennsylvanian (Virgilian) phylloid algal mound complex, Hueco Mountains, El Paso country, west Texas. In: Toomey DF, Nitecki MH (eds) Paleoalgology: contemporary research and applications. Springer, New York, pp 188–207Google Scholar
  32. Pray LC, Wray JL (1963) Porous algal facies (Pennsylvanian) Honaker Trail, San Juan Canyon, Utah. In: Bass RO, Sharps SL (eds) Shelf carbonates, Paradox Basin (4th field conference guidebook). Four Corners Geological Society, Durango, CO, USA, pp 204–234Google Scholar
  33. Qin J, Wu Y, Yan Y, Zu Z (1996) Hercynian-Indosinian sedimentary-tectonic evolution of the Nanpanjiang Basin. Acta Geol Sin 70:99–107Google Scholar
  34. Roberts HH, Aharon P, Phipps CV (1988) Morphology and sedimentology of Halimeda bioherms from the eastern Java Sea (Indonesia). Coral Reefs 6:161–172CrossRefGoogle Scholar
  35. Roberts HH, Phipps CV (1988) Proposed oceanographic controls on modern Indonesian reefs: a turn-off/turn-on mechanism in a monsoonal setting. In: Proceedings of the 6th international coral reef symposium, Townsville, Australia, August 1988, vol 3, pp 529–534Google Scholar
  36. Roberts HH, Phipps CV, Effendi L (1987) Halimeda bioherms of the eastern Java Sea, Indonesia. Geology 15:371–374CrossRefGoogle Scholar
  37. Samankassou E (2001) Internal structure and depositional environment of late Carboniferous mounds from the Cármenes Syncline, Cantabrian Mountains, Spain. Sediment Geol 145:235–252CrossRefGoogle Scholar
  38. Samankassou E (2003) Upper Carboniferous-Lower Permian buildups of the Carnic Alps, Austria-Italy. In: Ahr WM, Harris PM, Morgan WA, Somerville ID (eds) Permo-Carboniferous platforms and reefs. SEPM/AAPG Spec Publ 78:201–217Google Scholar
  39. Samankassou E, West RR (2002) Construction versus accumulation in phylloid algal mounds: an example of a small constructed mound in the Pennsylvanian of Kansas, USA. Palaeogeogr Palaeoclimatol Palaeoecol 185:379–389CrossRefGoogle Scholar
  40. Samankassou E, West RR (2003) Constructional and accumulational modes of fabrics in selected Pennsylvanian algal-dominated buildups in eastern Kansas, Midcontinent, USA. In: Ahr WM, Harris PM, Morgan WA, Somerville ID (eds) Permo-Carboniferous platforms and reefs. SEPM/AAPG Spec Publ 78:219–237Google Scholar
  41. Scotese CR (1997) Paleogeographic atlas, PALEOMAP progress report 90–0497. Department of Geology, University of Texas at Arlington, USA, 37 ppGoogle Scholar
  42. Soreghan GS, Giles KA (1999) Amplitudes of Late Pennsylvanian glacioeustasy. Geology 27:255–258CrossRefGoogle Scholar
  43. Toomey DF (1976) Paleosynecology of a Permian plant dominated marine community. Neues Jahrb Geol Paläontol Abhandlung 152:1–18Google Scholar
  44. Toomey DF (1980) History of a Late Carboniferous phylloid algal bank complex in northeastern New Mexico. Lethaia 13:249–267CrossRefGoogle Scholar
  45. Toomey DF (1983) The paleoecology of a “Middle Limestone Member” (Leavenworth) of an Upper Carboniferous (Stephanian) cyclothem, midcontinent, USA. Facies 8:113–190CrossRefGoogle Scholar
  46. Toomey DF (1991) Late Permian reefs of southern Tunisia: facies patterns and comparison with the Capitan reef, southwestern United States. Facies 25:119–146CrossRefGoogle Scholar
  47. Toomey DF, Babcock JAE (1983) Precambrian and Paleozoic algal carbonates, west Texas–southern New Mexico. Colorado School Mines Prof Contrib 11:1–345Google Scholar
  48. Toomey DF, Winland HD (1973) Rock and biotic facies associated with Middle Pennsylvanian (Desmoinesian) algal buildup, Nena Lucia field, Nolan County, Texas. AAPG Bull 57:1053–1074Google Scholar
  49. Torres AM (1995) Ivanovia tebagaensis was a cyathiform Permian codiacean membranous alga with dimorphic cortices. J Paleontol 69:381–387Google Scholar
  50. Torres AM, West RR, Sawin RS (1992) Calcipatera cottonwoodensis, a new membranous Late Paleozoic calcareous alga. J Paleontol 66:678–681Google Scholar
  51. Wahlman GP (2002) Upper Carboniferous-Lower Permian (Bashkirian-Kungurian) mounds and reefs. In: Kiessling W, Flügel E, Golonka J (eds) Phanerozoic reef patterns. SEPM Spec Publ 72:271–338Google Scholar
  52. Wilson JL (1972) Cyclic and reciprocal sedimentation in Virgilian strata of southern New Mexico. In: Elam JG, Chuber S (eds) Cyclic Sedimentation in the Permian Basin, 2nd ed. West Texas Geol Soc Publ 72(60):82–99Google Scholar
  53. Wilson JL (1975) Carbonate facies in geologic history. Springer, New York, 471 ppGoogle Scholar
  54. Wilson JL (1977) Regional distribution of phylloid algal mounds in late Pennsylvanian and Wolfcampian strata of southern New Mexico. In: Butler JH (ed) Geology of the Sacramento Mountains, Otero County. West Texas Geol Soc Publ New Mexico 77(68):1–7Google Scholar

Copyright information

© Springer-Verlag 2007

Authors and Affiliations

  • Gong Enpu
    • 1
  • Elias Samankassou
    • 2
    Email author
  • Guan Changqing
    • 1
  • Zhang Yongli
    • 1
  • Sun Baoliang
    • 1
  1. 1.Department of GeologyNortheastern UniversityShenyangChina
  2. 2.Department of GeosciencesUniversity of FribourgFribourgSwitzerland

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