Bayesian inference of hydraulic properties in and around a white fir using a process-based ecohydrologic model

We present a parameter estimation study of the Soil-Tree-Atmosphere Continuum (STAC) model, a process-based model that simulates water flow through an individual tree and its surrounding root zone. Parameters are estimated to optimize the model fit to observations of sap flux, stem water potential,...

Full description

Saved in:
Bibliographic Details
Published in:Environmental modelling & software : with environment data news 2019-05, Vol.115, p.76-85
Main Authors: Massoud, E.C., Purdy, A.J., Christoffersen, B.O., Santiago, L.S., Xu, C.
Format: Article
Language:English
Subjects:
Abies concolor
Bayesian analysis
Climate
Computer simulation
Drought
Ecohydrology
Hydraulic properties
Hydraulics
Mathematical models
MCMC
Moisture content
Parameter estimation
Parameter identification
Root distribution
Root zone
Soil properties
Soil water
Soil water storage
Statistical inference
Vegetation
Water flow
Water potential
Water properties
Water storage
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We present a parameter estimation study of the Soil-Tree-Atmosphere Continuum (STAC) model, a process-based model that simulates water flow through an individual tree and its surrounding root zone. Parameters are estimated to optimize the model fit to observations of sap flux, stem water potential, and soil water storage made for a white fir (Abies concolor) in the Sierra Nevada, California. Bayesian inference is applied with a likelihood function that considers temporal correlation of the model errors. Key vegetation properties are estimated, such as the tree's root distribution, tolerance to drought, and hydraulic conductivity and retention functions. We find the model parameters are relatively non-identifiable when considering just soil water storage. Overall, by utilizing multiple processes (e.g. sap flow, stem water potential, and soil water storage) during the parameter estimation, we find the simulations of the soil and tree water properties to be more accurate when compared to observed data. •The impact of soil water on vegetation is poorly represented in climate models.•New models like the STAC model are expected to better capture vegetation response to water stress.•We constrain model simulations to observations of sap flux and soil water content.•Most, but not all, model processes and parameters were informative or identifiable.•The approach used here can improve predictions of ecosystem water dynamics.
ISSN:1364-8152
1873-6726
DOI:10.1016/j.envsoft.2019.01.022