Mass Extinctions and Their Relationship With Atmospheric Carbon Dioxide Concentration: Implications for Earth's Future

Industrialization has raised the concentration of carbon dioxide (CO2) in Earth's atmosphere by half since 1770, posing a risk from ocean acidification to global biodiversity, including phytoplankton that synthesize approximately (∼) 50% of planetary oxygen. This risk is estimated here from the...

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Bibliographic Details
Published inEarth's future Vol. 11; no. 6
Main Author Davis, W. Jackson
Format Journal Article
LanguageEnglish
Published Bognor Regis John Wiley & Sons, Inc 01.06.2023
Wiley
Subjects
Acidification
acidification of the ocean
Anthropogenic factors
Atmosphere
Atmospheric depressions
benefit‐cost analysis
Biodiversity
Biodiversity loss
carbon cycling
Carbon dioxide
Carbon dioxide concentration
Carbon dioxide emissions
Climate change
Cretaceous
Dinosaurs
Earth
ecological prediction
Emissions
energy policy
environmental policy
Extinction
Fossil fuels
Global temperatures
impacts of global change
Intergovernmental Panel on Climate Change
Mass extinctions
mechanisms of mass extinctions
Ocean acidification
Oceans
Oxygen
Periodicities
Phytoplankton
Plankton
Radiative forcing
Species extinction
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Summary:Industrialization has raised the concentration of carbon dioxide (CO2) in Earth's atmosphere by half since 1770, posing a risk from ocean acidification to global biodiversity, including phytoplankton that synthesize approximately (∼) 50% of planetary oxygen. This risk is estimated here from the fossil record and implications for our energy and economic future are explored. Over the last 534 million years (Myr), 50 extinction events present as peaks of genus loss‐and‐recovery cycles, each spanning ∼3–40 Myr. Atmospheric CO2 concentration oscillates with percent genus loss, leading in phase by ∼4 Myr and sharing harmonic periodicities at ∼10, 26 and 63 Myr. Over the last 210 Myr, where data resolution is highest, biodiversity loss is correlated with atmospheric CO2 concentration, but not with long‐term global temperature nor with marginal radiative forcing of temperature by atmospheric CO2. The end‐Cretaceous extinction of the dinosaurs is anomalous, occurring during a 20‐million year depression in atmospheric CO2 concentration and rising global temperature. Today's atmospheric CO2 concentration, ∼421 parts per million by volume (ppmv), corresponds in the most recent marine fossil record to a biodiversity loss of 6.39%, implying that contemporary anthropogenic CO2 emissions are killing ocean life now. The United Nations Intergovernmental Panel on Climate Change projects that unabated fossil fuel use could elevate atmospheric CO2 concentration to 800 ppmv by 2100, approaching the 870 ppmv mean concentration of the last 19 natural extinction events. Reversing this first global anthropogenic mass extinction requires reducing net anthropogenic CO2 emissions to zero, optimally by 2% per year starting immediately. Plain Language Summary The rising concentration of carbon dioxide (CO2) in Earth's atmosphere from burning fossil fuels poses a risk to biodiversity from ocean acidification, threatening marine algae that produce ∼50% of planetary oxygen. This risk is estimated here based on the relationship between marine biodiversity loss and atmospheric CO2 concentration in the fossil record. Biodiversity loss varies cyclically with atmospheric CO2 concentration on million‐year timescales, but is not correlated with long‐term global temperature nor with radiative forcing (RF) of temperature by CO2. Atmospheric CO2 is therefore a plausible cause of past mass extinctions, while long‐term temperature change and RF by CO2 are excluded. Biodiversity and atmospheric CO2 cycle at periods similar to each other and to geological and astrophysical cycles, consistent with causal linkages. The concentration of CO2 in today's atmosphere corresponds to a decline in fossil biodiversity of 6.39%, implying that current human‐induced emissions of CO2 are killing ocean life now. The United Nations Intergovernmental Panel on Climate Change projects that continuation of the global fossil fuel economy could raise atmospheric CO2 to concentrations approaching the average of past mass extinctions by the year 2100. Arresting this first human‐induced global mass extinction requires eliminating net human‐induced emissions of CO2 starting immediately. Key Points Past mass extinctions are correlated with atmospheric CO2 concentration, but not with long‐term temperature nor radiative forcing by CO2 Present CO2 concentration is associated in the fossil record with a 6.39% genus loss, implying current human destruction of biodiversity Future anthropogenic mass extinction can be stopped only by cutting human emissions of CO2 to zero, optimally by 2% per year starting now
ISSN:2328-4277
2328-4277
DOI:10.1029/2022EF003336