2014
DOI: 10.1002/2014wr015700
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An integrated modeling framework for exploring flow regime and water quality changes with increasing biofuel crop production in theU.S.CornBelt

Abstract: To better address the dynamic interactions between human and hydrologic systems, we develop an integrated modeling framework that employs a System of Systems optimization model to emulate human development decisions which are then incorporated into a watershed model to estimate the resulting hydrologic impacts. The two models are run interactively to simulate the coevolution of coupled human-nature systems, such that reciprocal feedbacks between hydrologic processes and human decisions (i.e., human impacts on … Show more

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Cited by 31 publications
(31 citation statements)
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“…Climate change leads to an increase of the air temperature and more variable rainfall regimes, with severe consequences for the frequency and magnitude of droughts and flood events, and an accelerated meltdown of glaciers, which can increase the river runoff in the short term but ultimately alters the discharge regimes in the long term, for this ambitious task is the system dynamics (SD) model, which was originally developed by Forrester in 1961 [19], and is an approach for understanding the interactions among driving factors and interconnected sub-systems that drive the dynamic behavior of a system [48,49]. Over the years, a number of SD models have been developed for water balance simulation and have been used to evaluate various water-related solutions [50][51][52], such as water resource planning models [53][54][55][56], hydrologic extremes models [57], agriculture water management models [58,59], and water balance models, which have been developed to test water-related and environmental issues in developing countries where the data availability is lacking [60]. With this background, the SD model satisfies the requirements for a complex analysis of the Issyk-Kul water level fluctuations and its driving factors.…”
Section: Introductionmentioning
confidence: 99%
“…Climate change leads to an increase of the air temperature and more variable rainfall regimes, with severe consequences for the frequency and magnitude of droughts and flood events, and an accelerated meltdown of glaciers, which can increase the river runoff in the short term but ultimately alters the discharge regimes in the long term, for this ambitious task is the system dynamics (SD) model, which was originally developed by Forrester in 1961 [19], and is an approach for understanding the interactions among driving factors and interconnected sub-systems that drive the dynamic behavior of a system [48,49]. Over the years, a number of SD models have been developed for water balance simulation and have been used to evaluate various water-related solutions [50][51][52], such as water resource planning models [53][54][55][56], hydrologic extremes models [57], agriculture water management models [58,59], and water balance models, which have been developed to test water-related and environmental issues in developing countries where the data availability is lacking [60]. With this background, the SD model satisfies the requirements for a complex analysis of the Issyk-Kul water level fluctuations and its driving factors.…”
Section: Introductionmentioning
confidence: 99%
“…They range from complete earth system models that capture the socio-hydrological processes in quite a lot of detail in a spatially distributed manner, to stylized models that abstract the coupled socio-hydrologic system into a small number of interconnected subsystems, and everything in between. Examples of socio-hydrologic models in this hierarchy include the System of Systems model presented in Yaeger et al [2014], the stylized models presented in Srinivasan [2015] and van Emmerik et al [2014], and the more generic model presented in Di Baldassarre et al [2015].…”
Section: Socio-hydrologic Modeling: ''Doing Social Science Using Natumentioning
confidence: 99%
“…The more realistic, detailed, and place-based models are better suited to analyzing and quantifying the sociohydrologic interactions and feedbacks in real time in specific places [Yaeger et al, 2014]. They would involve substantial data collection and experimentation (e.g., detailed process modeling) to parameterize the social and hydrologic processes and the socio-hydrologic feedbacks.…”
Section: Socio-hydrologic Modeling: ''Doing Social Science Using Natumentioning
confidence: 99%
“…SWAT was calibrated using hydrological streamflow and nitrate load data from USGS for a 10-year period encompassing very dry and very wet years to simulate the hydrological impact of miscanthus on stream flows and nutrient loads (see details in Ng et al 2010). Following the calibration and validation, the SWAT model is used to estimate monthly water drainage and nitrate load from each grid under each of the different land covers (see the description in Yaeger et al 2014). The estimated nitrate yields in May (the month with the maximum contribution of nitrate) are shown in Figs.…”
Section: Numerical Modelmentioning
confidence: 99%