1932
0
  1. Home
  2. A-Z Publications
  3. Annual Review of Earth and Planetary Sciences
  4. Volume 51, 2023
  5. Article

Annual Review of Earth and Planetary Sciences

Volume 51, 2023

What Models Tell Us About the Evolution of Carbon Sources and Sinks over the Phanerozoic

Abstract

The current rapid increase in atmospheric CO, linked to the massive use of fossil fuels, will have major consequences for our climate and for living organisms. To understand what is happening today, it is informative to look at the past. The evolution of the carbon cycle, coupled with that of the past climate system and the other coupled elemental cycles, is explored in the field, in the laboratory, and with the help of numerical modeling. The objective of numerical modeling is to be able to provide a quantification of the processes at work on our planet. Of course, we must remain aware that a numerical model, however complex, will never include all the relevant processes, impacts, and consequences because nature is complex and not all the processes are known. This makes models uncertain. We are still at the beginning of the exploration of the deep-time Earth. In the present contribution, we review some crucial events in coupled Earth-climate-biosphere evolution over the past 540 million years, focusing on the models that have been developed and what their results suggest. For most of these events, the causes are complex and we are not able to conclusively pinpoint all causal relationships and feedbacks in the Earth system. This remains a largely open scientific field.

  • ▪  The era of the pioneers of geological carbon cycle modeling is coming to an end with the recent development of numerical models simulating the physics of the processes, including climate and the role of vegetation, while taking into account spatialization.
  • ▪  Numerical models now allow us to address increasingly complex processes, which suggests the possibility of simulating the complete carbon balance of objects as complex as a mountain range.
  • ▪  While most of the processes simulated by models are physical-chemical processes in which the role of living organisms is taken into account in a very simple way, via a limited number of parameters, models of the carbon cycle in deep time coupled with increasingly complex ecological models are emerging and are profoundly modifying our understanding of the evolution of our planet's surface.

Keyword(s): carbon cycleclimatedeep timemodelingweathering
Loading

Article metrics loading...

/content/journals/10.1146/annurev-earth-032320-092701
2023-05-31
2024-04-27
Loading full text...

Full text loading...

/deliver/fulltext/earth/51/1/annurev-earth-032320-092701.html?itemId=/content/journals/10.1146/annurev-earth-032320-092701&mimeType=html&fmt=ahah

Literature Cited

  1. Arnscheidt CW, Rothman DH. 2022. Presence or absence of stabilizing Earth system feedbacks on different time scales. Sci. Adv. 8:eadc9241
     [Google Scholar]
  2. Arvidson RS, Mackenzie FT, Guidry M. 2006. MAGic: a Phanerozoic model for the geochemical cycling of major rock-forming components. Am. J. Sci. 306:135–90
     [Google Scholar]
  3. Barron EJ. 1983. A warm, equable Cretaceous: the nature of the problem. Earth-Sci. Rev. 19:305–38
     [Google Scholar]
  4. Bergman NM, Lenton TM, Watson AJ. 2004. COPSE: a new model of biogeochemical cycling over Phanerozoic time. Am. J. Sci. 304:397–437
     [Google Scholar]
  5. Berner RA. 1994. Geocarb II: a revised model of atmospheric CO2 over Phanerozoic time. Am. J. Sci. 294:56–91
     [Google Scholar]
  6. Berner RA. 2004. The Phanerozoic Carbon Cycle Oxford, UK: Oxford Univ. Press
  7. Berner RA. 2006. GEOCARBSULF: a combined model for Phanerozoic atmospheric O2 and CO2. Geochim. Cosmochim. Acta 70:5653–64
     [Google Scholar]
  8. Berner RA, Lasaga AC, Garrels RM. 1983. The carbonate-silicate geochemical cycle and its effect on atmospheric carbon dioxide over the past 100 million years. Am. J. Sci. 283:641–83
     [Google Scholar]
  9. Berner RA, Maasch KA. 1996. Chemical weathering and controls on atmospheric O2 and CO2: fundamental principles were enunciated by J. J. Ebelmen in 1845. Geochim. Cosmochim. Acta 60:1633–37
     [Google Scholar]
  10. Braconnot P, Otto-Bliesner B, Harrison S, Joussaume S, Peterchmitt J-Y et al. 2007. Results of PMIP2 coupled simulations of the Mid-Holocene and Last Glacial Maximum—Part 1: experiments and large-scale features. Clim. Past 3:261–77
     [Google Scholar]
  11. Brady PV, Gislason SR. 1997. Seafloor weathering controls on atmospheric CO2 and global climate. Geochim. Cosmochim. Acta 61:965–73
     [Google Scholar]
  12. Brune S, Williams SE, Muller RD. 2017. Potential links between continental rifting, CO2 degassing and climate change through time. Nat. Geosci. 10:941–46
     [Google Scholar]
  13. Burke WH, Denison RE, Hetherington EA, Koepnick RB, Nelson HF, Otto JB. 1982. Variation of seawater 87Sr/86Sr throughout Phanerozoic time. Geology 10:516–19
     [Google Scholar]
  14. Caldeira K. 1992. Enhanced Cenozoic chemical weathering and the subduction of pelagic carbonate. Nature 357:578–81
     [Google Scholar]
  15. Carretier S, Goddéris Y, Delannoy T, Rouby D. 2014. Mean bedrock-to-saprolite conversion and erosion rates during mountain growth and decline. Geomorphology 209:39–52
     [Google Scholar]
  16. Caves JK, Jost AB, Lau KV, Maher K. 2016. Cenozoic carbon cycle imbalances and a variable weathering feedback. Earth Planet. Sci. Lett. 450:152–63
     [Google Scholar]
  17. Caves Rugenstein JK, Ibarra DE, Von Blanckenburg F 2019. Neogene cooling driven by land surface reactivity rather than increased weathering fluxes. Nature 571:99–102
     [Google Scholar]
  18. Cogné JP, Humler E. 2008. Global scale patterns of continental fragmentation: Wilson's cycles as a constraint for long-term sea-level changes. Earth Planet. Sci. Lett. 273:251–59
     [Google Scholar]
  19. Colbourn G, Ridgwell A, Lenton TM. 2015. The time scale of the silicate weathering negative feedback on atmospheric CO2. Glob. Biogeochem. Cycles 29:583–96
     [Google Scholar]
  20. Coogan LA, Gillis KM. 2013. Low-temperature alteration of the seafloor: impacts on ocean chemistry. Annu. Rev. Earth Planet. Sci. 46:21–45
     [Google Scholar]
  21. Dessert C, Dupré B, François LM, Schott J, Gaillardet J et al. 2001. Erosion of Deccan Traps determined by river geochemistry: impact on the global climate and the 87Sr/86Sr ratio of seawater. Earth Planet. Sci. Lett. 188:459–74
     [Google Scholar]
  22. Domeier M, Torsvik TH. 2019. Full-plate modelling in pre-Jurassic time. Geol. Mag. 156:261–80
     [Google Scholar]
  23. Donnadieu Y, Goddéris Y, Pierrehumbert R, Dromart G, Fluteau F, Jacob R 2006. A GEOCLIM simulation of climatic and biogeochemical consequences of Pangea breakup. Geochem. Geophys. Geosyst. 7:Q11019
     [Google Scholar]
  24. Drever JI. 1994. The effect of land plants on weathering rates of silicate minerals. Geochim. Cosmochim. Acta 58:2325–32
     [Google Scholar]
  25. Ebelmen JJ. 1845. Sur les produits de la décomposition des espèces minérales de la famille des silicates. Ann. Mines 7:3–66
     [Google Scholar]
  26. Edmond JM. 1992. Himalayan tectonics, weathering processes, and the strontium isotope record in marine limestones. Science 258:1594–97
     [Google Scholar]
  27. Engebretson DC, Kelley KP, Cashman HJ, Richards MA. 1992. 180 Million years of subduction. GSA Today 2:93–100
     [Google Scholar]
  28. France-Lanord C, Derry LA. 1997. Organic carbon burial forcing of the carbon cycle from Himalayan erosion. Nature 390:65–67
     [Google Scholar]
  29. François LM, Walker JCG, Opdyke BN. 1993. The history of global weathering and the chemical evolution of the ocean-atmosphere system. Geophys. Monogr. Series 74:143–59
     [Google Scholar]
  30. François LM, Goddéris Y. 1998. Isotopic constraints on the Cenozoic evolution of the carbon cycle. Chem. Geol. 145:177–212
     [Google Scholar]
  31. Gabet EJ, Mudd SM. 2009. A theoretical model coupling chemical weathering rates with denudation rates. Geology 37:151–54
     [Google Scholar]
  32. Gaffin S. 1987. Ridge volume dependence on seafloor generation rate and inversion using long term sealevel change. Am. J. Sci. 287:596–611
     [Google Scholar]
  33. Gaillardet J, Dupré B, Louvat P, Allègre CJ. 1999. Global silicate weathering and CO2 consumption rates deduced from the chemistry of large rivers. Chem. Geol. 159:3–30
     [Google Scholar]
  34. Galy A, France-Lanord C. 1999. Weathering processes in the Ganges-Brahmaputra basin and the riverine alkalinity budget. Chem. Geol. 159:31–60
     [Google Scholar]
  35. Galy V, France-Lanord C, Beyssac O, Faure P, Kudrass H, Palhol F. 2007. Efficient organic carbon burial in the Bengal fan sustained by the Himalayan erosional system. Nature 450:407–9
     [Google Scholar]
  36. Garrels RM, Perry EH. 1974. Cycling of carbon, sulfur, and oxygen through geologic time. The Sea, Vol. 5, ed. ED Goldberg303–36. New York: Wiley-Interscience
     [Google Scholar]
  37. Gerlach T. 2011. Volcanic versus anthropogenic carbon dioxide. Eos Trans. AGU 92:24201–2
     [Google Scholar]
  38. Gillis KM, Coogan LA. 2011. Secular variation in carbon uptake into the ocean crust. Earth Planet. Sci. Lett. 302:385–92
     [Google Scholar]
  39. Gislason SR, Oelkers EH, Eiriksdottir ES, Kardjilov MI, Gisladottir G et al. 2009. Direct evidence of the feedback between climate and weathering. Earth Planet. Sci. Lett. 277:213–22
     [Google Scholar]
  40. Goddéris Y, Donnadieu Y. 2019. A sink- or a source-driven carbon cycle at the geological timescale? Relative importance of palaeogeography versus solid Earth degassing rate in the Phanerozoic climatic evolution. Geol. Mag. 156:355–65
     [Google Scholar]
  41. Goddéris Y, Donnadieu Y, Carretier S, Aretz M, Dera G et al. 2017a. Onset and ending of the late Palaeozoic ice age triggered by tectonically paced rock weathering. Nat. Geosci. 10:382–86
     [Google Scholar]
  42. Goddéris Y, Donnadieu Y, Le Hir G, Lefebvre V, Nardin E 2014. The role of palaeogeography in the Phanerozoic history of atmospheric CO2 and climate. Earth-Sci. Rev. 128:122–38
     [Google Scholar]
  43. Goddéris Y, Francois LM. 1995. The Cenozoic evolution of the strontium and carbon cycles: relative importance of continental erosion and mantle exchanges. Chem. Geol. 126:169–90
     [Google Scholar]
  44. Goddéris Y, Le Hir G, Macouin M, Donnadieu Y, Hubert-Theou L et al. 2017b. Paleogeographic forcing of the strontium isotopic cycle in the Neoproterozoic. Gondwana Res. 42:151–62
     [Google Scholar]
  45. Gurung K, Field KJ, Batterman SA, Goddéris Y, Donnadieu Y et al. 2022. Climate windows of opportunity for plant expansion during the Phanerozoic. Nat. Commun. 13:4530
     [Google Scholar]
  46. Ibarra DE, Caves Rugenstein JK, Bachan A, Baresch A, Lau KV et al. 2019. Modeling the consequences of land plant evolution on silicate weathering. Am. J. Sci. 319:1–43
     [Google Scholar]
  47. IPCC (Intergov. Panel Clim. Change) 2021. Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to Sixth Assessment Report of the Intergovernmental Panel on Climate Change V Masson-Delmotte, P Zhai, A Pirani, SL Connors, C Péan et al. New York: Cambridge Univ. Press
  48. Isson TT, Planavsky NJ, Coogan LA, Stewart EM, Ague JJ et al. 2019. Evolution of the global carbon cycle and climate regulation on Earth. Glob. Biogeochem. Cycles 34:e2018GB006061
     [Google Scholar]
  49. Krause AJ, Mills BJW, Zhang S, Planavsky NJ, Lenton TM, Poulton SW. 2018. Stepwise oxygenation of the Paleozoic atmosphere. Nat. Commun. 9:4081
     [Google Scholar]
  50. Kump LR, Arthur MA. 1997. Global chemical erosion during the Cenozoic: Weatherability balances the budgets. Tectonic Uplift and Climate Change WF Ruddiman 399–426. New York: Springer US
     [Google Scholar]
  51. Le Hir G, Donnadieu Y, Goddéris Y, Meyer-Berthaud B, Ramstein G, Blakey RC 2011. The climate change caused by the land plant invasion in the Devonian. Earth Planet. Sci. Lett. 310:203–12
     [Google Scholar]
  52. Lee CTA, Thurner S, Paterson S, Cao WR. 2015. The rise and fall of continental arcs: interplays between magmatism, uplift, weathering, and climate. Earth Planet. Sci. Lett. 425::105–19
     [Google Scholar]
  53. Lefebvre V, Donnadieu Y, Goddéris Y, Fluteau F, Hubert-Theou L. 2013. Was the Antarctic glaciation delayed by a high degassing rate during the early Cenozoic?. Earth Planet. Sci. Lett. 371:203–11
     [Google Scholar]
  54. Lenton TM, Daines SJ, Mills BJW. 2018. COPSE reloaded: an improved model of biogeochemical cycling over Phanerozoic time. Earth-Sci. Rev. 178:1–28
     [Google Scholar]
  55. Longman J, Mills BJW, Donnadieu Y, Goddéris Y. 2022. Assessing volcanic controls on Miocene climate change. Geophys. Res. Lett. 49:2e2021GL096519
     [Google Scholar]
  56. Lord NS, Ridgwell A, Thorne MC, Lunt DJ. 2016. An impulse response function for the “long tail” of excess atmospheric CO2 in an Earth system model. Glob. Biogeochem. Cycles 30:2–17
     [Google Scholar]
  57. Maffre P, Godderis Y, Pohl A, Donnadieu Y, Carretier S, Le Hir G 2022. The complex response of continental silicate rock weathering to the colonization of the continents by vascular plants in the Devonian. Am. J. Sci. 322:461–92
     [Google Scholar]
  58. Maffre P, Swanson-Hysel NL, Goddéris Y 2021. Limited carbon cycle response to increased sulfide weathering due to oxygen feedback. Geophys. Res. Lett. 48:e2021GL094589
     [Google Scholar]
  59. Maher K, Chamberlain CP. 2014. Hydrologic regulation of chemical weathering and the geologic carbon cycle. Science 343:1502–4
     [Google Scholar]
  60. Marshall HG, Walker JCG, Kuhn WR. 1988. Long-term climate change and the geochemical cycle of carbon. J. Geophys. Res. 93:D1791–801
     [Google Scholar]
  61. Maslin M. 2004. Global Warming: A Very Short Introduction Oxford, UK: Oxford Univ. Press
  62. Matthaeus WJ, Macarewhich SI, Richey J, Montanez IP, McElwain JC et al. 2023. A systems approach to understanding how plants transformed Earth's environment in deep time. Annu. Rev. Earth Planet. Sci. 51:551–80
     [Google Scholar]
  63. McArthur JM, Howarth RJ, Shields GA, Zhou Y 2020. Strontium isotope stratigraphy. Geologic Time Scale 2020 FM Gradstein, JG Ogg, MD Schmitz, GM Ogg 211–38. Amsterdam: Elsevier
     [Google Scholar]
  64. McKenzie NR, Horton BK, Loomis SE, Stockli DF, Planavsky NJ, Lee CTA. 2016. Continental arc volcanism as the principal driver of icehouse-greenhouse variability. Science 352:444–47
     [Google Scholar]
  65. Millot R, Gaillardet J, Dupre B, Allegre CJ. 2002. The global control of silicate weathering rates and the coupling with physical erosion: new insights from rivers of the Canadian Shield. Earth Planet. Sci. Lett. 196:83–98
     [Google Scholar]
  66. Mills B, Daines SJ, Lenton TM. 2014. Changing tectonic controls on the long-term carbon cycle from Mesozoic to present. Geochem. Geophys. Geosyst. 15:4866–84
     [Google Scholar]
  67. Mills BJW, Donnadieu Y, Goddéris Y. 2021. Spatial continuous integration of Phanerozoic global biogeochemistry and climate. Gondwana Res 100:73–86
     [Google Scholar]
  68. Misra S, Froelich PN. 2012. Lithium isotope history of Cenozoic seawater: changes in silicate weathering and reverse weathering. Science 335:818–23
     [Google Scholar]
  69. Moquet J-S, Crave A, Viers J, Seyler P, Armijos E et al. 2011. Chemical weathering and atmospheric/soil CO2 uptake in the Andean and Foreland Amazon basins. Chem. Geol. 287:1–26
     [Google Scholar]
  70. Moulton KL, West J, Berner RA. 2000. Solute flux and mineral mass balance approaches to the quantification of plant effects on silicate weathering. Am. J. Sci. 300:539–70
     [Google Scholar]
  71. Müller RD, Mather B, Dutkiewicz A, Keller T, Merdith A et al. 2022. Evolution of Earth's tectonic carbon conveyor belt. Nature 605:629–39
     [Google Scholar]
  72. Oliva P, Viers J, Dupré B. 2003. Chemical weathering in granitic environments. Chem. Geol. 202:225–56
     [Google Scholar]
  73. Park Y, Maffre P, Goddéris Y, Swanson-Hysell NL. 2020. Emergence of the Southeast Asian islands as a driver for Neogene cooling. PNAS 117:25319–26
     [Google Scholar]
  74. Porder S. 2019. How plants enhance weathering and how weathering is important to plants. Elements 15:241–46
     [Google Scholar]
  75. Raymo ME. 1991. Geochemical evidence supporting T. C. Chamberlin's theory of glaciation. Geology 19:344–47
     [Google Scholar]
  76. Raymo ME, Ruddiman WF, Froelich PN. 1988. Influence of late Cenozoic mountain building on ocean geochemical cycles. Geology 16:649–53
     [Google Scholar]
  77. Richey JD, Montanez IP, Goddéris Y, Looy CV, Griffis NP, DiMichele WA. 2020. Influence of temporally varying weatherability on CO2-climate coupling and ecosystem change in the late Paleozoic. Clim. Past 16:1759–75
     [Google Scholar]
  78. Ridgwell A, Hargreaves J, Edwards N, Annan J, Lenton T et al. 2007. Marine geochemical data assimilation in an efficient Earth system model of global biogeochemical cycling. Biogeosciences 4:87–104
     [Google Scholar]
  79. Spence J, Telmer K. 2005. The role of sulfur in chemical weathering and atmospheric CO2 fluxes: evidence from major ions, δ13CDIC, and δ34SSO4 in rivers of the Canadian Cordillera. Geochim. Cosmochim. Acta 69:5441–48
     [Google Scholar]
  80. Spivack AJ, Staudigel H. 1994. Low-temperature alteration of the upper oceanic crust and the alkalinity budget of seawater. Chem. Geol. 115:239–47
     [Google Scholar]
  81. Staudigel H, Hart SR. 1983. Alteration of basaltic glass: mechanisms and significance for the oceanic crust-seawater budget. Geochim. Cosmochim. Acta 47:337–50
     [Google Scholar]
  82. Syvitski JPM, Milliman JD. 2007. Geology, geography, and humans battle for dominance over the delivery of fluvial sediment to the coastal ocean. J. Geol. 115:1–19
     [Google Scholar]
  83. Tierney JE, Poulsen CJ, Montanez IP, Bhattacharya T, Feng R et al. 2020. Past climates inform our future. Science 370:eaay3701
     [Google Scholar]
  84. Torres MA, West AJ, Clark KE, Paris G, Bouchez J et al. 2016. The acid and alkalinity budgets of weathering in the Andes–Amazon system: insights into the erosional control of global biogeochemical cycles. Geochim. Cosmochim. Acta 450:381–91
     [Google Scholar]
  85. Torres MA, West AJ, Li GJ. 2014. Sulphide oxidation and carbonate dissolution as a source of CO2 over geological timescales. Nature 507:346–49
     [Google Scholar]
  86. Veizer J, Ala D, Azmy K, Bruckschen P, Buhl D et al. 1999. 87Sr/86Sr, δ13C and δ18O evolution of Phanerozoic seawater. Chem. Geol. 161:59–88
     [Google Scholar]
  87. Vigier N, Goddéris Y. 2015. A new approach for modeling Cenozoic oceanic lithium isotope paleo-variations: the key role of climate. Clim. Past 11:635–45
     [Google Scholar]
  88. Volk T. 1989. Sensitivity of climate and atmospheric CO2 to deep-ocean and shallow-ocean carbonate burial. Nature 337:637–40
     [Google Scholar]
  89. Walker JCG, Hays PB, Kasting JF. 1981. A negative feedback mechanism for the long-term stabilization of Earth's surface temperature. J. Geophys. Res. 86:C109776–82
     [Google Scholar]
  90. Wallmann K, Flögel S, Scholz F, Dale AW, Kemena TP et al. 2019. Periodic changes in the Cretaceous ocean and climate caused by marine redox see-saw. Nat. Geosci. 12:456–61
     [Google Scholar]
  91. West AJ. 2012. Thickness of the chemical weathering zone and implications for erosional and climatic drivers of weathering and for carbon-cycle feedbacks. Geology 40:811–14
     [Google Scholar]
  92. West AJ, Galy A, Bickle M. 2005. Tectonic and climatic controls on silicate weathering. Earth Planet. Sci. Lett. 235:211–28
     [Google Scholar]
  93. Westbroeck P. 1991. Life as a Geological Force New York: W.W. Norton
  94. Willenbring JK, Von Blanckenburg F 2010. Long-term stability of global erosion rates and weathering during the late-Cenozoic cooling. Nature 465:211–14
     [Google Scholar]
  95. Wold CN, Hay WW. 1990. Estimating ancient sediment fluxes. Am. J. Sci. 290:1069–89
     [Google Scholar]
  96. Zeebe RE. 2012. LOSCAR: Long-term Ocean-atmosphere-Sediment CArbon cycle Reservoir Model v2.0.4. Geosci. Model Dev. 5:149–66
     [Google Scholar]
  97. Zeebe RE, Caldeira K. 2008. Close mass balance of long-term carbon fluxes from ice-core CO2 and ocean chemistry record. Nat. Geosci. 1:312–15
     [Google Scholar]
/content/journals/10.1146/annurev-earth-032320-092701
Loading
What Models Tell Us About the Evolution of Carbon Sources and Sinks over the Phanerozoic
Annual Review of Earth and Planetary Sciences 51, 471 (2023); https://doi.org/10.1146/annurev-earth-032320-092701
/content/journals/10.1146/annurev-earth-032320-092701
/content/journals/10.1146/annurev-earth-032320-092701
Loading

Data & Media loading...

  • Article Type: Review Article

Most Cited Most Cited RSS feed

This is a required field
Please enter a valid email address
Approval was a Success
Invalid data
An Error Occurred
Approval was partially successful, following selected items could not be processed due to error