Your search keyword '"VIC hydrological model"' showing total 3 results

1. Integration of 2D Lateral Groundwater Flow into the Variable Infiltration Capacity (VIC) Model and Effects on Simulated Fluxes for Different Grid Resolutions and Aquifer Diffusivities

Author

Johanna M. Scheidegger, Christopher R. Jackson, Sekhar Muddu, Sat Kumar Tomer, and Rosa Filgueira

Subjects

VIC hydrological model, groundwater model, soil moisture–groundwater coupling, grid resolution, aquifer diffusivity, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Better representations of groundwater processes need to be incorporated into large-scale hydrological models to improve simulations of regional- to global-scale hydrology and climate, as well as understanding of feedbacks between the human and natural systems. We incorporated a 2D groundwater flow model into the variable infiltration capacity (VIC) hydrological model code to address its lack of a lateral groundwater flow component. The water table was coupled with the variably saturated VIC soil column allowing bi-directional exchange of water between the aquifer and the soil. We then investigated how variations in aquifer properties and grid resolution affect modelled evapotranspiration (ET), runoff and groundwater recharge. We simulated nine idealised, homogenous aquifers with different combinations of transmissivity, storage coefficient, and three grid resolutions. The magnitude of cell ET, runoff, and recharge significantly depends on water table depth. In turn, the distribution of water table depths varied significantly as grid resolution increased from 1° to 0.05° for the medium and high transmissivity systems, resulting in changes of model-average fluxes of up to 12.3% of mean rainfall. For the low transmissivity aquifer, increasing the grid resolution has a minimal effect as lateral groundwater flow is low, and the VIC grid cells behave as vertical columns. The inclusion of the 2D groundwater model in VIC will enable the future representation of irrigation from groundwater pumping, and the feedbacks between groundwater use and the hydrological cycle.

Published

2021

2. Integration of 2D Lateral Groundwater Flow into the Variable Infiltration Capacity (VIC) Model and Effects on Simulated Fluxes for Different Grid Resolutions and Aquifer Diffusivities

Author

Sat Kumar Tomer, Rosa Filgueira, Johanna Scheidegger, Sekhar Muddu, Christopher R. Jackson, and University of St Andrews. School of Computer Science

Subjects

QA75, VIC hydrological model, lcsh:Hydraulic engineering, 010504 meteorology & atmospheric sciences, Groundwater flow, Water table, QA75 Electronic computers. Computer science, Geography, Planning and Development, 0207 environmental engineering, grid resolution, Soil science, Aquifer, 02 engineering and technology, Aquatic Science, soil moisture–groundwater coupling, 01 natural sciences, Biochemistry, aquifer diffusivity, lcsh:Water supply for domestic and industrial purposes, lcsh:TC1-978, Grid resolution, QE, Aquifer diffusivity, 020701 environmental engineering, 0105 earth and related environmental sciences, Water Science and Technology, GB, lcsh:TD201-500, geography, GE, geography.geographical_feature_category, Soil moisture-groundwater coupling, DAS, Groundwater recharge, groundwater model, Aquifer properties, QE Geology, Groundwater model, GB Physical geography, Environmental science, Surface runoff, Groundwater, GE Environmental Sciences

Abstract

Funding: The authors would like to acknowledge the support of the UK Natural Environment Research Council and Indian Ministry of Earth Science Newton Bhabha joint-funded project "Coupled Human and Natural Systems Environment (CHANSE)" (NERC grant NE/N01670X/1; MoES/NERC/16/02/10 PC-II). Better representations of groundwater processes need to be incorporated into large-scale hydrological models to improve simulations of regional- to global-scale hydrology and climate, as well as understanding of feedbacks between the human and natural systems. We incorporated a 2D groundwater flow model into the variable infiltration capacity (VIC) hydrological model code to address its lack of a lateral groundwater flow component. The water table was coupled with the variably saturated VIC soil column allowing bi-directional exchange of water between the aquifer and the soil. We then investigated how variations in aquifer properties and grid resolution affect modelled evapotranspiration (ET), runoff and groundwater recharge. We simulated nine idealised, homogenous aquifers with different combinations of transmissivity, storage coefficient, and three grid resolutions. The magnitude of cell ET, runoff, and recharge significantly depends on water table depth. In turn, the distribution of water table depths varied significantly as grid resolution increased from 1° to 0.05° for the medium and high transmissivity systems, resulting in changes of model-average fluxes of up to 12.3% of mean rainfall. For the low transmissivity aquifer, increasing the grid resolution has a minimal effect as lateral groundwater flow is low, and the VIC grid cells behave as vertical columns. The inclusion of the 2D groundwater model in VIC will enable the future representation of irrigation from groundwater pumping, and the feedbacks between groundwater use and the hydrological cycle. Publisher PDF

Published

2021

3. Integration of 2D Lateral Groundwater Flow into the Variable Infiltration Capacity (VIC) Model and Effects on Simulated Fluxes for Different Grid Resolutions and Aquifer Diffusivities.

Author

Scheidegger, Johanna M., Jackson, Christopher R., Muddu, Sekhar, Tomer, Sat Kumar, Filgueira, Rosa, and Morbidelli, Renato

Subjects

GROUNDWATER flow, WATER table, WATER distribution, GROUNDWATER, HYDROLOGIC cycle, AQUIFERS, HYDROLOGY, GROUNDWATER recharge

Abstract

Better representations of groundwater processes need to be incorporated into large-scale hydrological models to improve simulations of regional- to global-scale hydrology and climate, as well as understanding of feedbacks between the human and natural systems. We incorporated a 2D groundwater flow model into the variable infiltration capacity (VIC) hydrological model code to address its lack of a lateral groundwater flow component. The water table was coupled with the variably saturated VIC soil column allowing bi-directional exchange of water between the aquifer and the soil. We then investigated how variations in aquifer properties and grid resolution affect modelled evapotranspiration (ET), runoff and groundwater recharge. We simulated nine idealised, homogenous aquifers with different combinations of transmissivity, storage coefficient, and three grid resolutions. The magnitude of cell ET, runoff, and recharge significantly depends on water table depth. In turn, the distribution of water table depths varied significantly as grid resolution increased from 1° to 0.05° for the medium and high transmissivity systems, resulting in changes of model-average fluxes of up to 12.3% of mean rainfall. For the low transmissivity aquifer, increasing the grid resolution has a minimal effect as lateral groundwater flow is low, and the VIC grid cells behave as vertical columns. The inclusion of the 2D groundwater model in VIC will enable the future representation of irrigation from groundwater pumping, and the feedbacks between groundwater use and the hydrological cycle. [ABSTRACT FROM AUTHOR]

Published

2021