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A lithium-isotope perspective on the evolution of carbon and silicon cycles.

Boriana Kalderon-AsaelJoachim A R KatchinoffNoah J PlanavskyAshleigh V S HoodMathieu DellingerEric J BellefroidDavid S JonesAxel HofmannFrantz Ossa OssaFrancis A MacdonaldChunjiang WangTerry T IssonJack G MurphyJohn A HigginsA Joshua WestMalcolm W WallaceDan AsaelPhilip A E Pogge von Strandmann
Published in: Nature (2021)
The evolution of the global carbon and silicon cycles is thought to have contributed to the long-term stability of Earth's climate1-3. Many questions remain, however, regarding the feedback mechanisms at play, and there are limited quantitative constraints on the sources and sinks of these elements in Earth's surface environments4-12. Here we argue that the lithium-isotope record can be used to track the processes controlling the long-term carbon and silicon cycles. By analysing more than 600 shallow-water marine carbonate samples from more than 100 stratigraphic units, we construct a new carbonate-based lithium-isotope record spanning the past 3 billion years. The data suggest an increase in the carbonate lithium-isotope values over time, which we propose was driven by long-term changes in the lithium-isotopic conditions of sea water, rather than by changes in the sedimentary alterations of older samples. Using a mass-balance modelling approach, we propose that the observed trend in lithium-isotope values reflects a transition from Precambrian carbon and silicon cycles to those characteristic of the modern. We speculate that this transition was linked to a gradual shift to a biologically controlled marine silicon cycle and the evolutionary radiation of land plants13,14.
Keyphrases
  • solid state
  • climate change
  • gas chromatography
  • physical activity
  • high resolution
  • radiation induced