Bio-geodynamics of the Earth: State of the art and future directions

Abstract

<p>Geodynamic evolution of Earth’s mantle and lithosphere is inextricably linked to the evolution of its atmosphere, oceans, landscape and life (e.g., Stern, 2016; Pellissier et al., 2017; Zaffos et al., 2017; Zerkle. 2018). In this context, modern-style plate tectonics that was established gradually through geological time (e.g., Gerya, 2019) is often viewed as a strong promoter of biological evolution (e.g., Pellissier et al., 2017; Zerkle, 2018; Stern, 2016). The influences of this global tectono-magmatic style are at least twofold (e.g., Zerkle, 2018; Stern, 2016). Firstly, life is sustained by a critical set of elements contained within rock, ocean and atmosphere reservoirs and cycled between Earth’s surface and interior via various tectonic, magmatic and surface processes (Zerkle, 2018); plate tectonics is very effective for this recycling. Second, plate tectonics is an unparalleled agent for redistributing continents and oceans, growing mountain ranges, and forming land bridges, and provides continuous but moderate environmental pressures that isolate and stimulate populations to adapt and evolve (Stern, 2016). Importantly, modern-style plate tectonics itself exerts continuous moderate environmental pressures that drive evolution and stimulate populations to adapt and evolve without being capable of extinguishing all life (Stern 2016). The power of plate tectonics for both nutrient recycling and paleogeographic rededistributions  suggests that a planet with oceans, continents, and modern-style plate tectonics maximizes opportunities for speciation and natural selection, whereas a similar planet without plate tectonics provides fewer such opportunities (Stern, 2016).  The evolution of life must intimately reflect Earth’s tectonic evolution.</p><p>It is important to also point out that timescales of biological evolution of complex life estimated on the basis of the analysis of phylogenies and/or fossils are rather long and comparable to geodynamic timescales (e.g., Alroy, 2008; Marshall, 2017). This timescale similarity creates an opportunity for investigating lithospheric and mantle processes with life evolution by developing and testing novel hybrid bio-geodynamical numerical models. These are currently emerging. Here, we review state of the art for understanding the complex relationship between lithospheric dynamics and life evolution and present some recent examples of numerical modeling studies investigating Earth’s bio-geodynamic evolution.</p><p><strong> </strong><strong>References </strong></p><p>Alroy, J. (2008). Dynamics of origination and extinction in the marine fossil record. Proceedings of the National Academy of Sciences. 105, 11536.</p><p>Gerya, T. (2019) Geodynamics of the early Earth:  Quest for the missing paradigm. Geology, DOI:10.1130/focus-Oct2019.</p><p>Marshall, C. R. (2017). Five palaeobiological laws needed to understand the evolution of the living biota. Nature Ecology & Evolution, 1(6), 0165.</p><p>Pellissier, L., Heine, C., Rosauer, D.F., Albouy, C. (2017)  Are global hotspots of endemic richness shaped by plate tectonics? Biological Journal of the Linnean Society 123 (1), 247-261.</p><p>Stern, R.J. (2016) Is plate tectonics needed to evolve technological species on exoplanets? Geoscience Frontiers, 7, 573-580.</p><p>Zaffos, A., Finnegan, S, Peters, S.E. (2017) Plate tectonic regulation of global marine animal diversity. PNAS, 114, 5653–5658.</p><p>Zerkle A. L. (2018) Biogeodynamics: bridging the gap between surface and deep Earth processes. Phil. Trans. R. Soc. A 376, 20170401. (doi:10.1098/rsta.2017.0401)</p>