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This Special Issue includes papers on physical phenomena, such as wind-driven flows, coastal flooding, and turbidity currents, and modeling techniques, such as model comparison, model coupling, parallel computation, and domain decomposition. These papers illustrate the need for modeling coastal ocean flows with multiple physical processes at different scales. Additionally, these papers reflect the current status of such modeling of coastal ocean flows, and they present a roadmap with numerical methods, data collection, and artificial intelligence as future endeavors.
high performance computing --- HPC --- PETSc --- parallelization --- scalability --- parallel performance --- streams --- curvilinear --- non-hydrostatic --- ocean modeling --- GCCOM --- open boundaries --- domain decomposition --- variational data assimilation --- inverse problems --- shallow water equations --- boundary conditions --- mathematical modelling --- coastal ocean modelling --- computational methods --- hydrodynamic --- modeling --- sea level rise --- mobile application --- app --- crowdsourcing --- SCHISM --- Tidewatch --- StormSense --- Catch the King --- downstream blocking --- compound flooding --- coastal storm surge and inundation --- explosive lateral flooding --- hurricane inland and upland flooding --- coastal modelling --- operational forecasting --- model evaluation --- inter-comparison --- NEMO --- FVCOM --- Ocean Protection Plan --- turbidity current --- suspended sediment --- numerical model --- Gulf of Mexico --- cold front --- Hurricane Barry --- numerical simulation --- subtidal hydrodynamics --- multi-inlet --- volume flux --- multiscale --- multiphysics --- model coupling --- data collection --- machine learning
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This Special Issue includes papers on physical phenomena, such as wind-driven flows, coastal flooding, and turbidity currents, and modeling techniques, such as model comparison, model coupling, parallel computation, and domain decomposition. These papers illustrate the need for modeling coastal ocean flows with multiple physical processes at different scales. Additionally, these papers reflect the current status of such modeling of coastal ocean flows, and they present a roadmap with numerical methods, data collection, and artificial intelligence as future endeavors.
Technology: general issues --- History of engineering & technology --- high performance computing --- HPC --- PETSc --- parallelization --- scalability --- parallel performance --- streams --- curvilinear --- non-hydrostatic --- ocean modeling --- GCCOM --- open boundaries --- domain decomposition --- variational data assimilation --- inverse problems --- shallow water equations --- boundary conditions --- mathematical modelling --- coastal ocean modelling --- computational methods --- hydrodynamic --- modeling --- sea level rise --- mobile application --- app --- crowdsourcing --- SCHISM --- Tidewatch --- StormSense --- Catch the King --- downstream blocking --- compound flooding --- coastal storm surge and inundation --- explosive lateral flooding --- hurricane inland and upland flooding --- coastal modelling --- operational forecasting --- model evaluation --- inter-comparison --- NEMO --- FVCOM --- Ocean Protection Plan --- turbidity current --- suspended sediment --- numerical model --- Gulf of Mexico --- cold front --- Hurricane Barry --- numerical simulation --- subtidal hydrodynamics --- multi-inlet --- volume flux --- multiscale --- multiphysics --- model coupling --- data collection --- machine learning --- high performance computing --- HPC --- PETSc --- parallelization --- scalability --- parallel performance --- streams --- curvilinear --- non-hydrostatic --- ocean modeling --- GCCOM --- open boundaries --- domain decomposition --- variational data assimilation --- inverse problems --- shallow water equations --- boundary conditions --- mathematical modelling --- coastal ocean modelling --- computational methods --- hydrodynamic --- modeling --- sea level rise --- mobile application --- app --- crowdsourcing --- SCHISM --- Tidewatch --- StormSense --- Catch the King --- downstream blocking --- compound flooding --- coastal storm surge and inundation --- explosive lateral flooding --- hurricane inland and upland flooding --- coastal modelling --- operational forecasting --- model evaluation --- inter-comparison --- NEMO --- FVCOM --- Ocean Protection Plan --- turbidity current --- suspended sediment --- numerical model --- Gulf of Mexico --- cold front --- Hurricane Barry --- numerical simulation --- subtidal hydrodynamics --- multi-inlet --- volume flux --- multiscale --- multiphysics --- model coupling --- data collection --- machine learning
Choose an application
This Special Issue includes papers on physical phenomena, such as wind-driven flows, coastal flooding, and turbidity currents, and modeling techniques, such as model comparison, model coupling, parallel computation, and domain decomposition. These papers illustrate the need for modeling coastal ocean flows with multiple physical processes at different scales. Additionally, these papers reflect the current status of such modeling of coastal ocean flows, and they present a roadmap with numerical methods, data collection, and artificial intelligence as future endeavors.
Technology: general issues --- History of engineering & technology --- high performance computing --- HPC --- PETSc --- parallelization --- scalability --- parallel performance --- streams --- curvilinear --- non-hydrostatic --- ocean modeling --- GCCOM --- open boundaries --- domain decomposition --- variational data assimilation --- inverse problems --- shallow water equations --- boundary conditions --- mathematical modelling --- coastal ocean modelling --- computational methods --- hydrodynamic --- modeling --- sea level rise --- mobile application --- app --- crowdsourcing --- SCHISM --- Tidewatch --- StormSense --- Catch the King --- downstream blocking --- compound flooding --- coastal storm surge and inundation --- explosive lateral flooding --- hurricane inland and upland flooding --- coastal modelling --- operational forecasting --- model evaluation --- inter-comparison --- NEMO --- FVCOM --- Ocean Protection Plan --- turbidity current --- suspended sediment --- numerical model --- Gulf of Mexico --- cold front --- Hurricane Barry --- numerical simulation --- subtidal hydrodynamics --- multi-inlet --- volume flux --- multiscale --- multiphysics --- model coupling --- data collection --- machine learning
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This Special Issue comprises 11 papers that outline the advances in research on various aspects of climate change impacts on hydrologic extremes, including both drivers (temperature, precipitation, and snow) and effects (peak flow, low flow, and water temperature). These studies cover a broad range of topics on hydrological extremes, including hydro-climatic controls, trends, homogeneity, nonstationarity, compound events and associated uncertainties, for both historical and future climates.
Research & information: general --- Geography --- regional flood frequency analysis --- flood-related attribute --- region of influence --- flood region revision process --- Canadian annual maximum flow --- extreme precipitation --- LARS-WG --- CMIP5 --- spatiotemporal changes --- climate change --- climatic controls --- multiple linear regression --- permafrost region --- streamflow extremes --- trend analysis --- variable importance analysis --- extreme events --- hydrology --- concurrent --- Colorado River basin --- heatwaves --- drought --- flooding --- low flows --- multi-purpose reservoir --- functional volume --- uncertainties --- Monte Carlo method --- hydrological extremes --- simulation-optimization model --- optimal storage volume --- simulation model --- retention volume --- transformation of flood discharges --- CMIP6 --- extreme --- SWAT --- flood --- IHA --- global warming --- Malaysia --- Kelantan --- peak flows --- predictor --- predictand --- snow water equivalent --- annual maximum flow --- western Canada --- uncertainty --- riverine flooding --- coastal flooding --- compound flooding --- projected IDF curves --- design storm --- Stephenville Crossing --- snow --- trends --- Yakima River basin --- cascade reservoirs --- design flood --- nonstationary conditions --- equivalent reliability --- most likely regional composition --- dependence structure --- glacier ablation --- North Cascade Range --- salmon --- glacier mass balance --- heat wave --- n/a
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This Special Issue comprises 11 papers that outline the advances in research on various aspects of climate change impacts on hydrologic extremes, including both drivers (temperature, precipitation, and snow) and effects (peak flow, low flow, and water temperature). These studies cover a broad range of topics on hydrological extremes, including hydro-climatic controls, trends, homogeneity, nonstationarity, compound events and associated uncertainties, for both historical and future climates.
regional flood frequency analysis --- flood-related attribute --- region of influence --- flood region revision process --- Canadian annual maximum flow --- extreme precipitation --- LARS-WG --- CMIP5 --- spatiotemporal changes --- climate change --- climatic controls --- multiple linear regression --- permafrost region --- streamflow extremes --- trend analysis --- variable importance analysis --- extreme events --- hydrology --- concurrent --- Colorado River basin --- heatwaves --- drought --- flooding --- low flows --- multi-purpose reservoir --- functional volume --- uncertainties --- Monte Carlo method --- hydrological extremes --- simulation-optimization model --- optimal storage volume --- simulation model --- retention volume --- transformation of flood discharges --- CMIP6 --- extreme --- SWAT --- flood --- IHA --- global warming --- Malaysia --- Kelantan --- peak flows --- predictor --- predictand --- snow water equivalent --- annual maximum flow --- western Canada --- uncertainty --- riverine flooding --- coastal flooding --- compound flooding --- projected IDF curves --- design storm --- Stephenville Crossing --- snow --- trends --- Yakima River basin --- cascade reservoirs --- design flood --- nonstationary conditions --- equivalent reliability --- most likely regional composition --- dependence structure --- glacier ablation --- North Cascade Range --- salmon --- glacier mass balance --- heat wave --- n/a
Choose an application
This Special Issue comprises 11 papers that outline the advances in research on various aspects of climate change impacts on hydrologic extremes, including both drivers (temperature, precipitation, and snow) and effects (peak flow, low flow, and water temperature). These studies cover a broad range of topics on hydrological extremes, including hydro-climatic controls, trends, homogeneity, nonstationarity, compound events and associated uncertainties, for both historical and future climates.
Research & information: general --- Geography --- regional flood frequency analysis --- flood-related attribute --- region of influence --- flood region revision process --- Canadian annual maximum flow --- extreme precipitation --- LARS-WG --- CMIP5 --- spatiotemporal changes --- climate change --- climatic controls --- multiple linear regression --- permafrost region --- streamflow extremes --- trend analysis --- variable importance analysis --- extreme events --- hydrology --- concurrent --- Colorado River basin --- heatwaves --- drought --- flooding --- low flows --- multi-purpose reservoir --- functional volume --- uncertainties --- Monte Carlo method --- hydrological extremes --- simulation-optimization model --- optimal storage volume --- simulation model --- retention volume --- transformation of flood discharges --- CMIP6 --- extreme --- SWAT --- flood --- IHA --- global warming --- Malaysia --- Kelantan --- peak flows --- predictor --- predictand --- snow water equivalent --- annual maximum flow --- western Canada --- uncertainty --- riverine flooding --- coastal flooding --- compound flooding --- projected IDF curves --- design storm --- Stephenville Crossing --- snow --- trends --- Yakima River basin --- cascade reservoirs --- design flood --- nonstationary conditions --- equivalent reliability --- most likely regional composition --- dependence structure --- glacier ablation --- North Cascade Range --- salmon --- glacier mass balance --- heat wave --- regional flood frequency analysis --- flood-related attribute --- region of influence --- flood region revision process --- Canadian annual maximum flow --- extreme precipitation --- LARS-WG --- CMIP5 --- spatiotemporal changes --- climate change --- climatic controls --- multiple linear regression --- permafrost region --- streamflow extremes --- trend analysis --- variable importance analysis --- extreme events --- hydrology --- concurrent --- Colorado River basin --- heatwaves --- drought --- flooding --- low flows --- multi-purpose reservoir --- functional volume --- uncertainties --- Monte Carlo method --- hydrological extremes --- simulation-optimization model --- optimal storage volume --- simulation model --- retention volume --- transformation of flood discharges --- CMIP6 --- extreme --- SWAT --- flood --- IHA --- global warming --- Malaysia --- Kelantan --- peak flows --- predictor --- predictand --- snow water equivalent --- annual maximum flow --- western Canada --- uncertainty --- riverine flooding --- coastal flooding --- compound flooding --- projected IDF curves --- design storm --- Stephenville Crossing --- snow --- trends --- Yakima River basin --- cascade reservoirs --- design flood --- nonstationary conditions --- equivalent reliability --- most likely regional composition --- dependence structure --- glacier ablation --- North Cascade Range --- salmon --- glacier mass balance --- heat wave
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