An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South Korea

An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South Korea

Integrated surface water⁻groundwater (SW⁻GW) models could be used to assess the impacts of climate change or variability on the hydrological cycle. However, the damping effects of the hydrological system have rarely been explored via integrated SW⁻GW modeling. This pape...

Full description

Bibliographic Details
Main Authors: Jaewon Joo, Yong Tian, Chunmiao Zheng, Yi Zheng, Zan Sun, Aijing Zhang, Hyungjoon Chang
Format: Article
Language:English
Published: MDPI AG 2018-10-01
Series:Water
Subjects:
surface water–groundwater interactions
water balances
integrated hydrological model
GSFLOW
damping effects
Online Access:https://www.mdpi.com/2073-4441/10/11/1529
id doaj-68d02e728d664d1991beec3b24548d0c
record_format Article
spelling doaj-68d02e728d664d1991beec3b24548d0c2020-11-24T22:58:49ZengMDPI AGWater2073-44412018-10-011011152910.3390/w10111529w10111529An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South KoreaJaewon Joo0Yong Tian1Chunmiao Zheng2Yi Zheng3Zan Sun4Aijing Zhang5Hyungjoon Chang6School of Environmental Science and Engineering, Southern University of Science and Technology, Shenzhen 518055, ChinaSchool of Environmental Science and Engineering, Southern University of Science and Technology, Shenzhen 518055, ChinaSchool of Environmental Science and Engineering, Southern University of Science and Technology, Shenzhen 518055, ChinaSchool of Environmental Science and Engineering, Southern University of Science and Technology, Shenzhen 518055, ChinaInstitute of Water Sciences, Peking University, Beijing 100871, ChinaBureau of South to North Water Transfer of Planning, Designing and Management, Ministry of Water Resources, Beijing 100053, ChinaSchool of Civil Engineering, Chungbuk National University, Cheongju 361-763, KoreaIntegrated surface water⁻groundwater (SW⁻GW) models could be used to assess the impacts of climate change or variability on the hydrological cycle. However, the damping effects of the hydrological system have rarely been explored via integrated SW⁻GW modeling. This paper presents an integrated modeling study in a typical humid area, the Miho catchment in Korea, using an integrated model called Groundwater and Surface-water FLOW (GSFLOW). The major findings of this study are as follows: (1) The simulated results from 2005 to 2014 indicate that the temporal variability in the streamflow, stream-groundwater interactions and groundwater recharge are dominated by the precipitation, while the temporal variability in the evapotranspiration (ET) is controlled by the energy conditions; (2) Damping effects can affect the hydrological cycle across different temporal and spatial scales. At the catchment scale, the soil zone and aquifer play a dominant role in damping the precipitation on monthly and annual time scales, respectively; (3) Variability in the capacity to buffer earlier precipitation is found at small spatial scales, such as streams, and larger spatial scales, such as the whole catchment. This variability could affect the water balance at larger spatial scales and affect the hydrography recession at smaller spatial scales.https://www.mdpi.com/2073-4441/10/11/1529surface water–groundwater interactionswater balancesintegrated hydrological modelGSFLOWdamping effects
collection DOAJ
language English
format Article
sources DOAJ
author Jaewon Joo
Yong Tian
Chunmiao Zheng
Yi Zheng
Zan Sun
Aijing Zhang
Hyungjoon Chang
spellingShingle Jaewon Joo
Yong Tian
Chunmiao Zheng
Yi Zheng
Zan Sun
Aijing Zhang
Hyungjoon Chang
An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South Korea
Water
surface water–groundwater interactions
water balances
integrated hydrological model
GSFLOW
damping effects
author_facet Jaewon Joo
Yong Tian
Chunmiao Zheng
Yi Zheng
Zan Sun
Aijing Zhang
Hyungjoon Chang
author_sort Jaewon Joo
title An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South Korea
title_short An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South Korea
title_full An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South Korea
title_fullStr An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South Korea
title_full_unstemmed An Integrated Modeling Approach to Study the Surface Water-Groundwater Interactions and Influence of Temporal Damping Effects on the Hydrological Cycle in the Miho Catchment in South Korea
title_sort integrated modeling approach to study the surface water-groundwater interactions and influence of temporal damping effects on the hydrological cycle in the miho catchment in south korea
publisher MDPI AG
series Water
issn 2073-4441
publishDate 2018-10-01
description Integrated surface water⁻groundwater (SW⁻GW) models could be used to assess the impacts of climate change or variability on the hydrological cycle. However, the damping effects of the hydrological system have rarely been explored via integrated SW⁻GW modeling. This paper presents an integrated modeling study in a typical humid area, the Miho catchment in Korea, using an integrated model called Groundwater and Surface-water FLOW (GSFLOW). The major findings of this study are as follows: (1) The simulated results from 2005 to 2014 indicate that the temporal variability in the streamflow, stream-groundwater interactions and groundwater recharge are dominated by the precipitation, while the temporal variability in the evapotranspiration (ET) is controlled by the energy conditions; (2) Damping effects can affect the hydrological cycle across different temporal and spatial scales. At the catchment scale, the soil zone and aquifer play a dominant role in damping the precipitation on monthly and annual time scales, respectively; (3) Variability in the capacity to buffer earlier precipitation is found at small spatial scales, such as streams, and larger spatial scales, such as the whole catchment. This variability could affect the water balance at larger spatial scales and affect the hydrography recession at smaller spatial scales.
topic surface water–groundwater interactions
water balances
integrated hydrological model
GSFLOW
damping effects
url https://www.mdpi.com/2073-4441/10/11/1529
work_keys_str_mv AT jaewonjoo anintegratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT yongtian anintegratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT chunmiaozheng anintegratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT yizheng anintegratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT zansun anintegratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT aijingzhang anintegratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT hyungjoonchang anintegratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT jaewonjoo integratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT yongtian integratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT chunmiaozheng integratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT yizheng integratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT zansun integratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT aijingzhang integratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
AT hyungjoonchang integratedmodelingapproachtostudythesurfacewatergroundwaterinteractionsandinfluenceoftemporaldampingeffectsonthehydrologicalcycleinthemihocatchmentinsouthkorea
_version_ 1725646362486243328

Similar Items