AUTHOR=Fox David L. , Pau Stephanie , Taylor Lyla , Strömberg Caroline A. E. , Osborne Colin P. , Bradshaw Catherine , Conn Stephen , Beerling David J. , Still Christopher J. 

TITLE=Climatic Controls on C4 Grassland Distributions During the Neogene: A Model-Data Comparison

JOURNAL=Frontiers in Ecology and Evolution

VOLUME=6

YEAR=2018

URL=https://www.frontiersin.org/journals/ecology-and-evolution/articles/10.3389/fevo.2018.00147

DOI=10.3389/fevo.2018.00147

ISSN=2296-701X

ABSTRACT=<p>Grasslands dominated by taxa using the C<sub>4</sub> photosynthetic pathway first developed on several continents during the Neogene and Quaternary, long after C<sub>4</sub> photosynthesis first evolved among grasses. The histories of these ecosystems are relatively well-documented in the geological record from stable carbon isotope measurements (of fossil vertebrate herbivores and paleosols) and the plant microfossil record (pollen and/or phytolith assemblages). The distinct biogeography and ecophysiology of modern C<sub>3</sub> and C<sub>4</sub> grasses have led to hypotheses explaining the origins of C<sub>4</sub> grasslands in terms of long-term changes in the Earth system, such as increased aridity and decreasing atmospheric pCO<sub>2</sub>. However, quantitative proxies for key abiotic drivers of these hypotheses (e.g., temperature, precipitation, pCO<sub>2</sub>) are still in development, not yet widely applied at the continental or global scale or throughout the late Cenozoic, and/or remain contentious. Testing these hypotheses globally therefore remains difficult. To understand better the potential links between changes in the Earth system and the origin of C<sub>4</sub> grasslands, we undertook a global-scale comparison between observational records of C<sub>4</sub> plant abundances in Miocene and Pliocene localities compiled from the literature and three increasingly complex models of C<sub>4</sub> physiology, dominance, and abundance. The literature compilation comprises &gt;2,600 δ<sup>13</sup>C-values each of fossil terrestrial vertebrates and of paleosol carbonates, which we interpret as primarily proxies for the abundance of C<sub>4</sub> grasses, based on the modern contribution of C<sub>4</sub> grasses to terrestrial net primary productivity. We forced the vegetation models with simulated monthly climates from the HadCM3 family of coupled ocean-atmosphere general circulation models (OAGCMs) over a range of pCO<sub>2</sub>-values for each epoch to model C<sub>4</sub> dominance or abundance in grid cells as: (1) months per year exceeding the temperature at which net carbon assimilation is greater for C<sub>4</sub> than C<sub>3</sub> photosynthesis (<italic>crossover temperature model</italic>); (2) the number of months per year exceeding the crossover temperature and having sufficient precipitation for growth (≥25 mm/month; <italic>Collatz model</italic>); and (3) the Sheffield Dynamic Global Vegetation Model (<italic>SDGVM</italic>), which models multiple plant functional types (PFTs) (C<sub>3</sub> and C<sub>4</sub> grasses, evergreen, and deciduous trees). Model-data agreement is generally weak, although statistically significant for many comparisons, suggesting that regional to local ecological interactions, continent-specific plant evolutionary histories, and/or regional to local climatic conditions not represented in global scale OAGCMs may have been equally strong or stronger in driving the evolution of C<sub>4</sub> grasslands as global changes in the Earth system such as decreases in atmospheric pCO<sub>2</sub> and late Cenozoic global cooling and/or aridification.</p>