Hydrology and Water Resources Management in a Changing World.

Hydrology and Water Resources Management in a Changing World.

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Bibliographic Details
Superior document:In Focus - Special Book Series
:
Engeland, Kolbjø.
TeilnehmendeR:
Alfredsen, Knut.
Place / Publishing House:London : : IWA Publishing,, 2020.
{copy}2020.
Year of Publication:2020
Edition:1st ed.
Language:English
Series:In Focus - Special Book Series
Online Access:
Physical Description:1 online resource (246 pages)
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Table of Contents:
  • Cover
  • Contents
  • Editorial: Hydrology and water resources management in a changing world
  • ACKNOWLEDGEMENTS
  • REFERENCES
  • A dynamic river network method for the prediction of floods using a parsimonious rainfall-runoff model
  • ABSTRACT
  • INTRODUCTION
  • METHODOLOGY
  • Study catchments and data
  • The DDD rainfall-runoff model
  • Subsurface
  • Runoff dynamics
  • Model parameters and calibration
  • Dynamic river network routine
  • Correlation between Ac and Fc with environmental factors
  • RESULTS
  • Performance of DDD with and without dynamic river network
  • Correlation between Ac and Fc with environmental factors
  • DISCUSSION
  • Dynamic river networks
  • Correlation of Ac and Fc with environmental factors
  • CONCLUSIONS
  • ACKNOWLEDGEMENTS
  • REFERENCES
  • Testing the applicability of physiographic classification methods toward improving precipitation phase determination in conceptual models
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA
  • METHODS
  • Original-automated classification - all sites
  • New-automated method - all sites
  • Semi-manual method - all sites
  • Relief versus elevation - mountain and hill sites only
  • Station radius size - mountain and hill sites only
  • Calculations
  • RESULTS
  • All sites - comparison of three methods
  • Mountain and hill sites - relief versus elevation
  • Mountain and hill sites - station radius size
  • DISCUSSION
  • Automated versus semi-manual methods
  • Refinement of classification for topographically complex regions
  • CONCLUSIONS
  • SUPPLEMENTARY MATERIAL
  • REFERENCES
  • Precipitation phase uncertainty in cold region conceptual models resulting from meteorological forcing time-step intervals
  • ABSTRACT
  • INTRODUCTION
  • METHOD
  • RESULTS AND DISCUSSION
  • CONCLUSIONS
  • REFERENCES
  • Can model-based data products replace gauge data as input to the hydrological model?
  • ABSTRACT.
  • INTRODUCTION
  • STUDY AREA AND DATA
  • Study area
  • Data
  • METHODS
  • Data comparison
  • HBV model
  • Performance evaluation of datasets
  • RESULTS
  • Data comparison
  • Performance in simulating the hydrological response
  • Parameter uncertainty
  • DISCUSSION
  • CONCLUSIONS
  • ACKNOWLEDGEMENTS
  • CONFLICT OF INTEREST
  • SUPPLEMENTARY MATERIAL
  • REFERENCES
  • Evaluation of global forcing datasets for hydropower inflow simulation in Nepal
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA
  • DATA AND METHODS
  • Meteorological forcing data
  • Observed data
  • Reanalysis and regional climate model data
  • Topographical and land cover datasets
  • Spatial interpolation of observed and gridded forcing data
  • Hydrological model
  • Gamma snow
  • Parameters and calibration
  • Water balance estimation
  • Model performance evaluation
  • RESULTS
  • Meteorological forcing data analysis
  • Model parameters
  • Evaluation of discharge simulation using different forcing datasets
  • Water balance analysis
  • DISCUSSION
  • Discussion on model parameters
  • Potential factors controlling hydrological model efficiency during model calibration and validation
  • Discussion on the water balance analysis
  • Uncertainty in the model simulation and observation
  • CONCLUSIONS
  • FUNDING
  • ACKNOWLEDGEMENT
  • SUPPLEMENTARY MATERIAL
  • REFERENCES
  • Improving hydropower inflow forecasts by assimilating snow data
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA AND DATA
  • Refsdal catchment
  • Model forcing data
  • Snow and inflow observations
  • METHODS
  • METHODS
  • Model description
  • Data assimilation algorithm
  • Forcing ensemble generation
  • Description of experiments
  • RESULTS
  • DISCUSSION
  • CONCLUSIONS
  • ACKNOWLEDGEMENTS
  • REFERENCES
  • Reproducing different types of changes in hydrological indicators with rainfall-runoff models
  • ABSTRACT
  • INTRODUCTION
  • METHODOLOGY.
  • Datasets and catchments
  • Hydrological model
  • Indices of hydrological alteration
  • Study set-up
  • Estimation of changes in the hydrological indices
  • Evaluation metrics
  • Data analysis
  • RESULTS AND DISCUSSION
  • How do models calibrated with different objective functions differ in their ability to reproduce IHAs?
  • Which objective function is most suitable for modelling IHA changes?
  • How well can we estimate the direction of IHA changes?
  • How well can we estimate the magnitude of IHA changes?
  • Analysing the impact of the direction of change on the reproducibility of IHA changes
  • Identification of catchment descriptors influencing the quality of the IHA estimates
  • Limitations of the study
  • SUMMARY AND CONCLUSIONS
  • DATA AVAILABILITY STATEMENT
  • ACKNOWLEDGEMENTS
  • SUPPLEMENTARY MATERIAL
  • REFERENCES
  • Uncertainty of annual runoff projections in Lithuanian rivers under a future climate
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA AND DATA
  • METHODS
  • RESULTS AND DISCUSSION
  • CONCLUSIONS
  • REFERENCES
  • Response of melt water and rainfall runoff to climate change and their roles in controlling streamflow changes of the two upstream basins over the Tibetan Plateau
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA AND DATA
  • Study area
  • Data
  • METHOD
  • Hydrological model
  • Model parameters
  • Trends and attribution analyses
  • RESULTS
  • Model validation
  • Runoff components
  • The controlling roles of runoff components in the trend of river flow for the past 50 years
  • DISCUSSION
  • The hydrological role of melt runoff
  • Model uncertainty
  • CONCLUSIONS
  • ACKNOWLEDGEMENTS
  • REFERENCES
  • How extreme can unit discharge become in steep Norwegian catchments?
  • ABSTRACT
  • INTRODUCTION
  • Norwegian floods
  • European flash floods
  • The study area and the flood event
  • METHODS AND DATA.
  • Hydraulic modelling and data for estimation of the peak flood discharge
  • Methods and data for estimating the precipitation
  • Rainfall-runoff modelling and data for estimating the peak discharge
  • RESULTS
  • Calculated discharge at the dam crest
  • Simulated precipitation and discharge
  • DISCUSSION
  • CONCLUSIONS
  • ACKNOWLEDGEMENTS
  • REFERENCES
  • Features and causes of catastrophic floods in the Nemunas River basin
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA AND DATA
  • METHODS
  • RESULTS AND DISCUSSION
  • Hydrological characteristics of investigated floods
  • Characteristics of the meteorological conditions before catastrophic floods in 1958 and 1979
  • Spatial distribution of meteorological conditions in the Nemunas River basin
  • Variability and spatial distribution of runoff coefficients in WGS catchments of the Nemunas River basin
  • CONCLUSIONS
  • SUPPLEMENTARY MATERIAL
  • REFERENCES
  • Risk assessment for areas prone to flooding and subsidence: a case study from Bergen, Western Norway
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA AND DATA
  • Drainage system in Bergen city
  • Flood modelling
  • Present-day storm surge
  • Subsidence data
  • METHODOLOGY - RISK ASSESSMENT APPROACH
  • Description of the simple grid overlay method (1)
  • Description of the 'hot spot analysis' with aggregated flood areas method (2)
  • RESULTS AND DISCUSSION
  • Datasets and selected methods for analysis
  • Subsidence data
  • Flood data
  • Simple grid overlay - method 1
  • 'Hot spot analysis' - method 2
  • Risk assessment map combined with the existing drainage system
  • Risk assessment as a tool for end-users
  • CONCLUSIONS
  • Further work
  • ACKNOWLEDGEMENTS
  • REFERENCES
  • Limitations in using runoff coefficients for green and gray roof design
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA AND DATA
  • METHODS
  • Laboratory measurements
  • Field measurements.
  • RESULTS AND DISCUSSION
  • Laboratory measured runoff coefficients
  • Runoff coefficients based on field data
  • CONCLUSION
  • ACKNOWLEDGEMENTS
  • REFERENCES
  • Detection and attribution of flood responses to precipitation change and urbanization: a case study in Qinhuai River Basin, Southeast China
  • ABSTRACT
  • INTRODUCTION
  • STUDY AREA AND DATA
  • METHODS
  • Selection of flood series
  • Detect trend of the flood series
  • Frequency analysis
  • Attribution analysis
  • RESULTS
  • Changes in characteristics of flood series from the baseline period to the urbanization period
  • Trends of flood series from the baseline period to the urbanization period
  • Changes in the return period of flood series from the baseline period to the urbanization period
  • Evaluation of causative precipitation and urbanization impacts on changes in flood size
  • DISCUSSION
  • Effects of two different sampling methods on flood change evaluation
  • Attribution of trends in flood time series
  • CONCLUSIONS
  • ACKNOWLEDGEMENTS
  • REFERENCES
  • Usage of SIMWE model to model urban overland flood: a case study in Oslo
  • ABSTRACT
  • INTRODUCTION
  • METHODS
  • SIMWE model
  • Classification flood risk levels of urban flood
  • STUDY AREA AND DATA
  • Study area
  • Data
  • A case study at Grefsen
  • RESULTS
  • Inundation area and water depth
  • Classification of urban flood risks
  • DISCUSSION
  • CONCLUSIONS
  • ACKNOWLEDGEMENTS
  • REFERENCES.

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