The Impact of Soil Tension on Isotope Fractionation, Transport, and Interpretations of the Root Water Uptake Origin

Author:

Zhou Tiantian1ORCID,Šimůnek Jiří1ORCID,Nasta Paolo2ORCID,Brunetti Giuseppe3ORCID,Gaj Marcel4ORCID,Neukum Christoph5,Post Vincent6ORCID

Affiliation:

1. Department of Environmental Sciences University of California Riverside Riverside CA USA

2. Department of Agricultural Sciences AFBE Division University of Naples Federico II Napoli Italy

3. Department of Civil Engineering University of Calabria Rende Italy

4. Department of Hydrology State Agency for Nature, Environment and Consumer Protection Minden Germany

5. Federal Institute for Geosciences and Natural Resources (BGR) Hannover Germany

6. Edinsi Groundwater Nederhorst den Berg The Netherlands

Abstract

AbstractThe new isotope module in HYDRUS‐1D can be used to infer the origin of root water uptake (RWU), a suitable dynamic indicator for agriculture and forest water management. However, evidence shows that the equilibrium fractionation between liquid water and water vapor within the soil is affected not only by soil temperature but also by soil tension. How soil tension affects isotope transport modeling and interpretations of the RWU origin is still unknown. In this study, we evaluated three fractionation scenarios on model performance for a field data set from Langeoog Island: (a) no fractionation (Non_Frac), (b) the soil temperature control on equilibrium fractionation as described by the standard Craig‐Gordon equation (CG_Frac), and (c) CG_Frac plus the soil tension control on equilibrium fractionation (CGT_Frac). The model simulations showed that CGT_Frac led to more depleted isotopic compositions of surface soil water than CG_Frac. The vertical origin of RWU was estimated using the water balance (WB) calculations and the Bayesian mixing model (SIAR). While the former directly used water flow outputs, the latter used as input simulated isotopic compositions (using different fractionation scenarios) of RWU and soil water. Both methods provided similar variation trends with time and depth in different soil layers' contributions to RWU. The contributions of all soil layers interpreted by the CGT_Frac scenario were always between Non_Frac and CG_Frac. The temporal origin of RWU was deduced from particle tracking (PT, releasing one hypothetical particle for individual precipitation event and tracking its movement based on the water balance between particles) and a virtual tracer experiment (VTE, assigning a known isotope composition to individual precipitation event and tracking its movement based on the cumulative isotope flux). Both methods revealed similar variation trends with time in drainage and root zone (RZ) travel times. The interpreted drainage and RZ travel times were generally ranked as Non_Frac > CGT_Frac > CG_Frac. Overall, the factors considered in the standard CG equation dominated isotope fractionation, transport, and interpretations of the RWU origin. Isotope transport‐based methods (SIAR, VTE) were more computationally demanding than water flow‐based methods (WB, PT).

Funder

National Institute of Food and Agriculture

Publisher

American Geophysical Union (AGU)

Subject

Water Science and Technology

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