Review: Current and emerging methods for catchment-scale modelling of recharge and evapotranspiration from shallow groundwater | Revue: Méthodes courantes et émergentes pour la modélisation de la recharge à l’échelle du bassin versant et de l’évapotranspiration d’eaux souterraines peu profondes Revisión: Métodos actuales y emergentes para el modelado de la recarga y la evapotranspiración a escala de cuenca para agua subterránea somera 综述:现有及新兴的流域范围浅层地下水的补给及蒸散量的建模方法 Revisão: Métodos atuais e emergentes para a modelagem de recarga e evapotranspiração de aquíferos livres em escala de bacia

A review is provided of the current and emerging methods for modelling catchment-scale recharge and evapotranspiration (ET) in shallow groundwater systems. With increasing availability of data, such as remotely sensed reflectance and land-surface temperature data, it is now possible to model groundwater recharge and ET with more physically realistic complexity and greater levels of confidence. The conceptual representation of recharge and ET in groundwater models is critical in areas with shallow groundwater. The depth dependence of recharge and vegetation water-use feedback requires additional calibration to fluxes as well as heads. Explicit definition of gross recharge vs. net recharge, and groundwater ET vs. unsaturated zone ET, in preparing model inputs and reporting model results is necessary to avoid double accounting in the water balance. Methods for modelling recharge and ET include (1) use of simple surface boundary conditions for groundwater flow models, (2) coupling saturated groundwater models with one-dimensional unsaturated-zone models, and (3) more complex fully-coupled surface-unsaturated-saturated conceptualisations. Model emulation provides a means for including complex model behaviours with lower computational effort. A precise ET surface input is essential for accurate model outputs, and the model conceptualisation depends on the spatial and temporal scales under investigation. Using remote sensing information for recharge and ET inputs in model calibration or in model–data fusion is an area for future research development. Improved use of uncertainty analysis to provide probability bounds for groundwater model outputs, understanding model sensitivity and parameter dependence, and guidance for further field-data acquisition are also areas for future research.