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Soil Carbon Dioxide Planetary Thermostat.

Gregory J Retallack
Published in: Astrobiology (2022)
Biological regulation of planetary temperature has been explained with the Daisyworld model, in which reflective-cooling white daises balance absorbing-warming black daisies. This article advances the proposition that cooling "daisies" of Daisyworld represent carbon sequestration and consumption by productive soils and ecosystems, such as grasslands expanding into deserts and tropical forests migrating toward the poles. On the other hand, warming "daisies" represent continued CO 2 emissions from volcanoes and springs allowed by unproductive frigid and desert ecosystems. Greenhouse spikes of CO 2 in deep time from large perturbations, such as flood basalt eruptions and asteroid impacts, did not continue as lethal runaway greenhouses, such as Venus, nor did low CO 2 of ice ages decline to a sterile global snowball, such as Mars. These hypotheses are quantified and tested by new global soil maps derived from paleosols of the last extremes of atmospheric CO 2 : middle Miocene (16 Ma) and last glacial maximum (20 ka), when CO 2 levels were 588 ± 72 and 180 ppm, respectively. Observed expansion of productive soils curbed large atmospheric injections of CO 2 in deep time and observed expansion of unproductive soils during ice ages of low CO 2 was thwarted by continued metamorphic and volcanic degassing. This short-term Soilworld thermostat of biogeographic redistribution of ecosystems supplemented long-term evolution of terrestrial carbon sequestration curbing solar radiation increases over billions of years. Similar agricultural management of ecosystems has potential for short-term carbon sequestration.
Keyphrases
  • climate change
  • human health
  • carbon dioxide
  • heavy metals
  • risk assessment
  • particulate matter
  • municipal solid waste
  • organic matter
  • radiation therapy
  • ultrasound guided
  • air pollution
  • plant growth