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Maximum entropy production, carbon assimilation, and the spatial organization of vegetation in river basins

Abstract: The spatial organization of functional vegetation types in river basins is a major determinant of their runoff production, biodiversity, and ecosystem services. The optimization of different objective functions has been suggested to control the adaptive behavior of plants and ecosystems, often without a compelling justification. Maximum entropy production (MEP), rooted in thermodynamics principles, provides a tool to justify the choice of the objective function controlling vegetation organization. The application of MEP at the ecosystem scale results in maximum productivity (i.e., maximum canopy photosynthesis) as the thermodynamic limit toward which the organization of vegetation appears to evolve. Maximum productivity, which incorporates complex hydrologic feedbacks, allows us to reproduce the spatial macroscopic organization of functional types of vegetation in a thoroughly monitored river basin, without the need for a reductionist description of the underlying microscopic dynamics. The methodology incorporates the stochastic characteristics of precipitation and the associated soil moisture on a spatially disaggregated framework. Our results suggest that the spatial organization of functional vegetation types in river basins naturally evolves toward configurations corresponding to dynamically accessible local maxima of the maximum productivity of the ecosystem.

Otras publicaciones de la misma revista o congreso con autores/as de la Universidad de Cantabria

 Autoría: Del Jesus M., Foti R., Rinaldo A., Rodriguez-Iturbe I.,

 Fuente: Proceedings of the National Academy of Sciences of the United States of America December 18, 2012 109 (51) 20837-20841

Editorial: National Academy of Sciences

 Fecha de publicación: 01/12/2012

Nº de páginas: 5

Tipo de publicación: Artículo de Revista

 DOI: 10.1073/pnas.1218636109

ISSN: 0027-8424,1091-6490

Url de la publicación: https://www.pnas.org/content/109/51/20837