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Ecological regulation of chemical weathering recorded in rivers.

Authors :
Druhan, Jennifer L.
Bouchez, Julien
Source :
Earth & Planetary Science Letters. Sep2024, Vol. 641, pN.PAG-N.PAG. 1p.
Publication Year :
2024

Abstract

We provide a new generalized framework accounting for the effects of water and nutrient uptake by roots in the weathering zone on broad patterns of solute concentration - discharge relationships in rivers. As plants withdraw water from the subsurface, they decrease the area-normalized fluid drainage rate. This results in a discharge flux to springs and streams which is a function of water use by plants, leading to ecosystem regulation of the characteristic timescales of chemical weathering reactions and fluid flow rate. Our predictive framework quantifies the pore water and river solute chemistry generated from water-rock interactions, regulated by the effects of vegetation on water flow rates. To this we add the capacity for vegetation to enrich, passively admit, or discriminate against a given dissolved solute based on ecophysiological needs, thus further modifying the local concentration of a given chemical species in solution across a weathering profile. This uptake flux is not lost to the atmosphere in the same manner as water is removed from the subsurface via evapotranspiration. Rather, these extracted chemical species become incorporated into the topsoil as litter which may be partially or fully resolubilized, creating an upper boundary condition which depends on the uptake and recycling characteristics of the ecosystem. These processes are united through a new solution to the advection-reaction equation which allows vegetation to regulate broad patterns of stream concentration - discharge relationships. We show that ecosystems are capable of both accelerating and impeding water-rock reaction rates across the weathering profile, ultimately leading to both thermodynamic and ecological controls on the baseflow concentration of rock-derived solutes in rivers. • We offer a new predictive model for the water and nutrient demands of ecosystems. • Plants to both enhance and impede mineral weathering reactions. • Plants modulate the relationship between river chemistry and flow rate. • River chemistry reflects both thermodynamic and ecological controls. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
0012821X
Volume :
641
Database :
Academic Search Index
Journal :
Earth & Planetary Science Letters
Publication Type :
Academic Journal
Accession number :
178148450
Full Text :
https://doi.org/10.1016/j.epsl.2024.118800