7.9 Terrestrial Environments

  • Lee R. Kump
  • Kalle Kirsimäe
  • Victor A. Melezhik
  • Alexander T. Brasier
  • Anthony E. Fallick
  • Paula E. Salminen
Chapter
First Online:
Part of the Frontiers in Earth Sciences book series (FRONTIERS)

Abstract

In contrast to a rather extensive marine sedimentary record of the Palaeoproterozoic, the terrestrial record, preserved as palaeosols (ancient soils; Retallack 2001) and caliches or calcretes (carbonate layers in palaeosols; Wright and Tucker 1991), is sparse. Nevertheless, these deposits are important, because they have the potential to provide the least ambiguous information on climatic and atmospheric compositional change during this critical interval of Earth history. In the best of circumstances, marine sediments record oceanic conditions, which can differ markedly from atmospheric conditions, especially in terms of redox. In the modern world, soil environments themselves poorly reflect those at the surface, especially in terms of CO2 and O2 partial pressure, because of respiration by roots and soil microbes. But in the Palaeoproterozoic, with its presumably poorly developed terrestrial biota, soil conditions likely track those of the atmosphere much more closely. (We use “presumably” here, because terrestrial ecosystems may have been extensive (Horodyski and Knauth 1994; Watanabe et al. 2000), and the land surface may have been the incubator for early evolutionary innovation, including the origin of cyanobacteria; e.g. Battistuzzi et al. 2009).

Keywords

Terrestrial Environment Greenstone Belt Baltic Shield Fennoscandian Shield Sediment Geol 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
This is a preview of subscription content, log in to check access.

Preview

Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.

References

  1. Andrews JE (2006) Palaeoclimatic records from stable isotopes in riverine tufas: synthesis and review. Earth Sci Rev 75:85–104Google Scholar
  2. Andrews JE, Brasier AT (2005) Seasonal records of climatic change in annually laminated tufas: short review and future prospects. J Quaternary Sci 20:411–421Google Scholar
  3. Andrews JE, Riding R, Dennis PF (1993) Stable isotopic compositions of recent freshwater cyanobacterial carbonates from the British Isles: local and regional environmental controls. Sedimentology 40:303–314Google Scholar
  4. Andrews JE, Riding R, Dennis PF (1997) The stable isotope record of environmental and climatic signals in modern terrestrial microbial carbonates from Europe. Palaeogeogr Palaeocl Palaeoecol 129:171–189Google Scholar
  5. Anzalone E, Ferreri V, Sprovieri M, D’Argenio B (2007) Travertines as hydrologic archives: the case of the Pontecagnano deposits (southern Italy). Adv Water Resour 30:2159–2175Google Scholar
  6. Arenas C, Gutiérrez F, Osácar C, Sancho C (2000) Sedimentology and geochemistry of fluvio-lacustrine tufa deposits controlled by evaporite solution subsidence in the central Ebro Depression, NE Spain. Sedimentology 47:883–909Google Scholar
  7. Awramik SM, Buchheim HP (2009) A giant, Late Archean lake system: the Meentheena member (Tumbiana Formation; Fortescue Group), Western Australia. Precambrian Res 174:215–240Google Scholar
  8. Bolhar R, Van Kranendonk MJ (2007) A non-marine depositional setting for the northern Fortescue Group, Pilbara Craton, inferred from trace element geochemistry of stromatolitic carbonates. Precambrian Res 155:229–250Google Scholar
  9. Bonny SM, Jones B (2008) Petrography and textural development of inorganic and biogenic lithotypes in a relict barite tufa deposit at Flybye Springs, NT, Canada. Sedimentology 55:275–303Google Scholar
  10. Brasier AT (2011) Searching for travertines, calcretes and speleothems in deep time: processes, appearances, predictions and the impact of plants. Earth Sci Rev. 104(4):213–239. doi: 10.1016/j.earscirev.2010.10.007Google Scholar
  11. Brasier AT, Andrews JE, Kendall AC (2011) Diagenesis or dire genesis? The origin of columnar spar in tufa stromatolites of central Greece and the role of Chironomid larvae. Sedimentology. doi: 10.1111/J.1365-3091.2010.01208.xGoogle Scholar
  12. Brasier AT, Andrews JE, Marca-Bell AD, Dennis PF (2010) Depositional continuity of seasonally laminated tufas: implications for δ18O based palaeotemperatures. Global Planet Change 71:160–167Google Scholar
  13. Chafetz HS, Folk RL (1984) Travertines: depositional morphology and the bacterially constructed constituents. J Sediment Petrol 54:289–316Google Scholar
  14. Chafetz HS, Lawrence JR (1994) Stable isotopic variability within modern travertines. Géogr Phys Quatern 48:257–273Google Scholar
  15. Chafetz HS, Utech NM, Fitzmaurice SP (1991) Differences in the delta 18 O and delta 13C signatures of seasonal laminae comprising travertine stromatolites. J Sediment Res 61:1015–1028Google Scholar
  16. Cohen AS, Thouin C (1987) Nearshore carbonate deposits in Lake Tanganyika. Geology 15:414–418Google Scholar
  17. Cotter E (1978) The evolution of fluvial style, with special reference to the central Appalachian Paleozoic. In: Miall AD (ed) Fluvial sedimentology, vol 5, Canadian Society of Petroleum Geologists Memoir. Canadian Society of Petroleum Geologists, Calgary, pp 361–383Google Scholar
  18. Davies NS, Gibling MR (2010) Cambrian to Devonian evolution of alluvial systems: the sedimentological impact of the earliest land plants. Earth Sci Rev 98:171–200Google Scholar
  19. Davis DW, Paces JB (1990) Time resolution of geologic events on the Keweenaw Peninsula and implications for development of the Midcontinent Rift system. Earth Planet Sci Lett 97:54–64Google Scholar
  20. Eggleston JR, Dean WE (1976) Chapter 8.7 Freshwater stromatolitic bioherms in Green Lake, New York. In: Walter M (ed) Developments in sedimentology, vol 20. Elsevier, Amsterdam, pp 479–488Google Scholar
  21. Elmore RD (1983) Precambrian non-marine stromatolites in alluvial fan deposits, the Copper Harbor Conglomerate, upper Michigan. Sedimentology 30:829–842Google Scholar
  22. Fairchild IJ, Borsato A, Tooth AF, Frisia S, Hawkesworth CJ, Huang Y, McDermott F, Spiro B (2000) Controls on trace element (Sr-Mg) compositions of carbonate cave waters: implications for speleothem climatic records. Chem Geol 166:255–269Google Scholar
  23. Ford TD, Pedley HM (1996) A review of tufa and travertine deposits of the world. Earth Sci Rev 41:117–175Google Scholar
  24. Fouke BW, Farmer JD, Des Marais DJ, Pratt L, Sturchio NC, Burns PC, Discipulo MK (2000) Depositional facies and aqueous-solid geochemistry of travertine-depositing hot springs (Angel Terrace, Mammoth Hot Springs, Yellowstone National Park, U.S.A.). J Sediment Res 70:565–585Google Scholar
  25. Freytet P, Plet A (1996) Modern freshwater microbial carbonates: the Phormidium stromatolites (tufa-travertine) of southeastern Burgundy (Paris Basin, France). Facies 34:219–237Google Scholar
  26. Freytet P, Verrecchia EP (1998) Freshwater organisms that build stromatolites: a synopsis of biocrystallization by prokaryotic and eukaryotic algae. Sedimentology 45:535–563Google Scholar
  27. Frisia S, Borsato A (2010) Karst. In: Alonso-Zarza AM, Tanner LH (eds) Developments in sedimentology, vol 61. Elsevier, Amsterdam, pp 269–318Google Scholar
  28. Garnett ER, Andrews JE, Preece RC, Dennis PF (2004) Climatic change recorded by stable isotopes and trace elements in a British Holocene tufa. J Quaternary Sci 19:251–262Google Scholar
  29. Grotzinger JP (1986) Cyclicity and paleoenvironmental dynamics, Rocknest platform, northwest Canada. Geol Soc Am Bull 97:1208–1231Google Scholar
  30. Grotzinger JP (1989) Facies and evolution of Precambrian carbonate depositional systems: emergence of the modern platform archetype. In: Crevello PD, Wilson JW, Sarg JF, Read JF (eds) Controls on carbonate platform and basin development. SEPM, Tulsa, pp 79–106Google Scholar
  31. Grotzinger JP, Knoll AH (1995) Anomalous carbonate precipitates: is the Precambrian the key to the Permian? Palaios 10:578–596Google Scholar
  32. Guido DM, Campbell KA (2009) Jurassic hot-spring activity in a fluvial setting at La Marciana, Patagonia, Argentina. Geol Mag 146:617–622Google Scholar
  33. Guidry SA, Chafetz HS (2003) Anatomy of siliceous hot springs: examples from Yellowstone National Park, Wyoming, USA. Sediment Geol 157:71–106Google Scholar
  34. Guo L, Riding R (1992) Aragonite laminae in hot water travertine crusts, Rapolano Terme, Italy. Sedimentology 39:1067–1079Google Scholar
  35. Guo L, Riding R (1994) Origin and diagenesis of Quaternary travertine shrub fabrics, Rapolano Terme, central Italy. Sedimentology 41:499–520Google Scholar
  36. Guo L, Riding R (1998) Hot-spring travertine facies and sequences, Late Pleistocene, Rapolano Terme, Italy. Sedimentology 45:163–180Google Scholar
  37. Guo L, Andrews J, Riding R, Dennis P, Dresser Q (1996) Possible microbial effects of stable carbon isotopes in hot-spring travertines. J Sediment Res 66:468–473Google Scholar
  38. Hammer Ø, Dysthe DK, Jamtveit B (2007) The dynamics of travertine dams. Earth Planet Sci Lett 256:258–263Google Scholar
  39. Hoffman P (1976) Environmental diversity of Middle Precambrian stromatolites. In: Walter M (ed) Stromatolites, Developments in sedimentology. Elsevier, Amsterdam, pp 599–611Google Scholar
  40. Ihlenfeld C, Norman MD, Gagan MK, Drysdale RN, Maas R, Webb J (2003) Climatic significance of seasonal trace element and stable isotope variations in a modern freshwater tufa. Geochim Cosmochim Acta 67:2341–2357Google Scholar
  41. Irion G, Muller G (1968) Mineralogy, petrology and chemical composition of some calcareous tufa from the Schwabische Alb, Germany. In: Muller G, Friedman GM (eds) Recent developments in carbonate sedimentology in Central Europe. Springer, Berlin, pp 157–171Google Scholar
  42. Janssen A, Swennen R, Podoor N, Keppens E (1999) Biological and diagenetic influence in Recent and fossil tufa deposits from Belgium. Sediment Geol 126:75–95Google Scholar
  43. Kawai T, Kano A, Hori M (2009) Geochemical and hydrological controls on biannual lamination of tufa deposits. Sediment Geol 213:41–50Google Scholar
  44. Koban C, Schweigert G (1993) Microbial origin of travertine fabrics – two examples from Southern Germany (Pleistocene stuttgart travertines and miocene riedöschingen Travertine). Facies 29:251–263Google Scholar
  45. Lindsay JF, Brasier MD, McLoughlin N, Green OR, Fogel M, Steele A, Mertzman SA (2005) The problem of deep carbon – an Archean paradox. Precambrian Res 143:1–22Google Scholar
  46. Love KM, Chafetz HS (1988) Diagenesis of laminated travertine crusts, Arbuckle Mountains, Oklahoma. J Sediment Res 58:441–445Google Scholar
  47. Matsuoka J, Kano A, Oba T, Watanabe T, Sakai S, Seto K (2001) Seasonal variation of stable isotopic compositions recorded in a laminated tufa, SW Japan. Earth Planet Sci Lett 192:31–44Google Scholar
  48. Melezhik VA, Fallick AE (2001) Palaeoproterozoic travertines of volcanic affiliation from a 13C-rich rift lake environment. Chem Geol 173:293–312Google Scholar
  49. Melezhik VA, Fallick AE, Grillo SM (2004) Subaerial exposure surfaces in a Palaeoproterozoic 13C-rich dolostone sequence from the Pechenga Greenstone Belt: palaeoenvironmental and isotopic implications for the 2330–2060 Ma global isotope excursion of 13C/12C. Precambrian Res 133:75–103Google Scholar
  50. Melezhik VA, Huhma H, Condon DJ, Fallick AE, Whitehouse MJ (2007) Temporal constraints on the Paleoproterozoic Lomagundi-Jatuli carbon isotopic event. Geology 35:655–658Google Scholar
  51. Merz MUE (1992) The biology of carbonate precipitation by Cyanobacteria. Facies 26:81–102Google Scholar
  52. Nehza O, Woo KS, Lee KC (2009) Combined textural and stable isotopic data as proxies for the mid-Cretaceous paleoclimate: a case study of lacustrine stromatolites in the Gyeongsang Basin, SE Korea. Sediment Geol 214:85–99Google Scholar
  53. O’Brien GR, Kaufman DS, Sharp WD, Atudorei V, Parnell RA, Crossey LJ (2006) Oxygen isotope composition of annually banded modern and mid-Holocene travertine and evidence of paleomonsoon floods, Grand Canyon, Arizona, USA. Quaternary Res 65:366–379Google Scholar
  54. Pedley HM (1990) Classification and environmental models of cool freshwater tufas. Sediment Geol 68:143–154Google Scholar
  55. Pedley M, González Martín JA, Ordóñez S, García Del Cura MA (2003) Sedimentology of Quaternary perched springline and paludal tufas: criteria for recognition, with examples from Guadalajara Province, Spain. Sedimentology 50:23–44Google Scholar
  56. Pelechaty SM, James NP (1991) Dolomitized middle Proterozoic calcretes, Bathurst Inlet, Northwest Territories, Canada. J Sediment Res 61:988–1001Google Scholar
  57. Pelechaty SM, James NP, Kerans C, Grotzinger JP (1991) A middle Proterozoic palaeokarst unconformity and associated sedimentary rocks, Elu Basin, northwest Canada. Sedimentology 38:775–797Google Scholar
  58. Pentecost A (1990) The formation of travertine shrubs; Mammoth Hot Springs, Wyoming. Geol Mag 127:159–168Google Scholar
  59. Pentecost A (1993) British travertines: a review. Proc Geologist Assoc 104:23–39Google Scholar
  60. Pentecost A (1995) The quaternary travertine deposits of Europe and Asia Minor. Quaternary Sci Rev 14:1005–1028Google Scholar
  61. Pentecost A, Spiro B (1990) Stable carbon and oxygen isotope composition of calcites associated with modern freshwater cyanobacteria and algae. Geomicrobiol J 8:17–26Google Scholar
  62. Pentecost A, Viles H (1994) A review and reassessment of Travertine classification. Geogr Phys Quatern 48:305–314Google Scholar
  63. Rainbird RH, Davis WJ, Stern RA, Peterson TD, Smith SR, Parrish RR, Hadlari T (2006) Ar-Ar and U-Pb Geochronology of a Late Paleoproterozoic Rift Basin: support for a genetic link with Hudsonian orogenesis, Western Churchill Province, Nunavut, Canada. J Geol 114:1–17Google Scholar
  64. Rainey DK, Jones B (2009) Abiotic versus biotic controls on the development of the Fairmont Hot Springs carbonate deposit, British Columbia, Canada. Sedimentology 56:1832–1857Google Scholar
  65. Riding R (1979) Origin and diagenesis of lacustrine algal bioherms at the margin of the Ries crater, Upper Miocene, southern Germany. Sedimentology 26:645–680Google Scholar
  66. Riding R (1991) Classification of microbial carbonates. In: Riding R (ed) Calcareous algae and stromatolites. Springer, Berlin, pp 21–51Google Scholar
  67. Riding R (2000) Microbial carbonates: the geological record of calcified bacterial-algal mats and biofilms. Sedimentology 47:179–214Google Scholar
  68. Riding R (2008) Abiogenic, microbial and hybrid authigenic crusts: components of Precambrian stromatolites. Geologia Croatica 61:73–103Google Scholar
  69. Risacher F, Eugster HP (1979) Holocene pisoliths and encrustations associated with spring-fed surface pools, Pastos Grandes, Bolivia. Sedimentology 26:253–270Google Scholar
  70. Rogerson M, Pedley HM, Wadhawan JD, Middleton R (2008) New insights into biological influence on the geochemistry of freshwater carbonate deposits. Geochim Cosmochim Acta 72:4976–4987Google Scholar
  71. Skotnicki SJ, Knauth LP (2007) The Middle Proterozoic Mescal Paleokarst, Central Arizona, U.S.A.: karst development, silicification, and cave deposits. J Sediment Res 77:1046–1062Google Scholar
  72. Soligo M, Tuccimei P, Barberi R, Delitala MC, Miccadei E, Taddeucci A (2002) U/Th dating of freshwater travertine from Middle Velino Valley (Central Italy): paleoclimatic and geological implications. Palaeogeogr Palaeocl Palaeoecol 184:147–161Google Scholar
  73. Soreghan MJ, Cohen AS (1996) Textural and compositional variability across littoral segments of Lake Tanganyika: the effect of asymmetric basin structure on sedimentation in Large Rift Lakes. Am Assoc Petrol Geologist Bull 80:382–409Google Scholar
  74. Szulc J, Cwizewicz M (1989) The lower permian freshwater carbonates of the Slawkow graben, Southern Poland: sedimentary facies context and stable isotope study. Palaeogeogr Palaeocl Palaeoecol 70:107–120Google Scholar
  75. Takashima C, Kano A (2008) Microbial processes forming daily lamination in a stromatolitic travertine. Sediment Geol 208:114–119Google Scholar
  76. Thrailkill J (1976) Speleothems. In: Walter MR (ed) Stromatolites. Elsevier, Amsterdam, pp 73–86Google Scholar
  77. Wacey D, Wright DT, Boyce AJ (2007) A stable isotope study of microbial dolomite formation in the Coorong Region, South Australia. Chem Geol 244:155–174Google Scholar
  78. Walter MR (1996) Ancient hydrothermal ecosystems on Earth: a new palaeobiological frontier. In: Evolution of hydrothermal ecosystems on Earth (and Mars?), vol 202, Ciba foundation symposium. Wiley, Chichester, pp 112–127Google Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2013

Authors and Affiliations

  • Lee R. Kump
    • 1
  • Kalle Kirsimäe
    • 2
  • Victor A. Melezhik
    • 3
    • 4
  • Alexander T. Brasier
    • 5
  • Anthony E. Fallick
    • 6
  • Paula E. Salminen
    • 7
  1. 1.Department of GeosciencesPennsylvanian State UniversityUniversity ParkUSA
  2. 2.Department of GeologyTartu UniversityTartuEstonia
  3. 3.Geological Survey of NorwayTrondheimNorway
  4. 4.Centre for GeobiologyUniversity of BergenBergenNorway
  5. 5.Faculty of Earth and Life SciencesVU University AmsterdamAmsterdamthe Netherlands
  6. 6.Scottish Universities Environmental Research CentreGlasgowUK
  7. 7.Department of Geosciences and GeographyUniversity of HelsinkiHelsinkiFinland

Personalised recommendations