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Thermochronologic perspectives on the deep-time evolution of the deep biosphere

Henrik Drake, Peter W. Reiners

2021Proceedings of the National Academy of Sciences26 citationsDOIOpen Access PDF

Abstract

The Earth's deep biosphere hosts some of its most ancient chemolithotrophic lineages. The history of habitation in this environment is thus of interest for understanding the origin and evolution of life. The oldest rocks on Earth, formed about 4 billion years ago, are in continental cratons that have experienced complex histories due to burial and exhumation. Isolated fracture-hosted fluids in these cratons may have residence times older than a billion years, but understanding the history of their microbial communities requires assessing the evolution of habitable conditions. Here, we present a thermochronological perspective on the habitability of Precambrian cratons through time. We show that rocks now in the upper few kilometers of cratons have been uninhabitable (>∼122 °C) for most of their lifetime or have experienced high-temperature episodes, such that the longest record of habitability does not stretch much beyond a billion years. In several cratons, habitable conditions date back only 50 to 300 million years, in agreement with dated biosignatures. The thermochronologic approach outlined here provides context for prospecting and interpreting the little-explored geologic record of the deep biosphere of Earth's cratons, when and where microbial communities may have thrived, and candidate areas for the oldest records of chemolithotrophic microbes.

Topics & Concepts

CratonBiospherePrecambrianEarth scienceGeologySnowball EarthAstrobiologyContext (archaeology)Geologic recordGeologic time scaleMacroevolutionPaleontologyEcologyTectonicsBiologyPhylogeneticsBiochemistryGlacial periodStructural basinGenePaleontology and Stratigraphy of FossilsGeology and Paleoclimatology ResearchMethane Hydrates and Related Phenomena
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