Hydrocomplexity: New Tools for Solving Wicked Water Problems


Monitoring and Evaluating the Water Cycle



Yüklə 214,71 Kb.
səhifə2/4
tarix29.10.2017
ölçüsü214,71 Kb.
#20291
1   2   3   4

Monitoring and Evaluating the Water Cycle





Back to the basics of understanding ET W. James Shuttleworth

13

KSOM clustering as a possible cure for the wicked water problem of inadequate data for water resources planning Adebayo J. Adeloye & Rabee Rustum

35

Mathematical modelling of water resources at the University of South Australia John Boland

37

Basin water quality network design: optimum sampling sites located by information theory Janaína Bezerra Mesquita & Sergio Koide

39

A national water census: quantifying, forecasting, and securing freshwater for America’s future Matthew C. Larsen & Eric J. Evenson

41

Use of modern technologies in estimating unaccounted water uses in the Murray-Darling Basin, Australia Awadhesh Prasad

43

Harmonisation of thematic maps in the European Union – setting up different types of environmental analytical maps Vanda Turczi, Philippe Quodverte & Jesús Reyes Nuñez

46

2

Linking Climate Change with Water Cycle Management




Groundwater and global hydrological change – current challenges and new insight R. Taylor, L. Longuevergne, R. Harding, M. Todd, B. Hewitson, U. Lall, K. Hiscock, H. Treidel, K. Dev Sharma, N. Kukuric, W. Stuckmeier &
M. Shamsudduha


51

Practical approaches to water management under climate change uncertainty Eugene Z. Stakhiv

62

Towards risk-based river basin management as an approach to overcome wicked water problems Jos Brils

70

Assessing adaptive capacity of water governance regimes under climatic uncertainty Margot Hill

72

Creation of adaptation mechanisms: the key to more cost-effective and environment-friendly water management Inom Normatov, Uktam Murtazaev & Nabi Nasirov

74

Modelling water availability and climate change with satellite remote sensing data Ebenezer Yemi Ogunbadewa

77

Development of an integrated model INDOCLIM for understanding the future state of a river basin Heru Santoso & Hery Harjono

79

3

Parsimonious vs Complicated Approaches




A parsimonious modelling approach for water management in dryland areas Saket Pande, Hubert H. G. Savenije, Luis. A. Bastidas & Ashvin K. Gosain

85

An approach for matching accuracy and predictive capability in hydrological model development F. Fenicia, H. H. G. Savenije & L. Hoffmann

91

Time series-based soft computing tool for wicked water problems Bindu Garg

100

Hydrochemical characterization of groundwater in the Guadalquivir River aquifer in western Jaén: application of geostatistical techniques
Rosario Jiménez-Espinosa & Juan Jiménez-Millán

102

Application of WMS in flow discharge prediction for the ungauged Wadi Bougous, Algeria K. Khanchoul, Z. Boukhrissa & A. Bouchebcheb

104

Modélisation des eaux de la Rivière Sebou, vers une gestion transdisciplinaire Mohammed Igouzal & Abdellatif Maslouhi

106

4

Whole-of-System and Adaptative Approaches




Modelling and decision making in water resource management
Hector M. Malano

111

5

Need for Transdisciplinary Issues Approaches to Deal with Water-related Ecosystems




Hydroinformatics and ecohydrology tools for ecologically sustainable development in northern China Huili Gong, Jing Zhang, Demin Zhou,
Xiaojuan Li & Yun Pan


129

Considering aquatic habitat properties in integrated river basin management – an ecohydrological modelling approach Jens Kiesel, Nicola Fohrer &
Britta Schmalz


137

Managing the impacts of climate change on water governance Beatrice Mosello

140

6

Integrated Approaches




A spiral approach to IWRM: the IWRM Guidelines at River Basin Level
Yasuro Nakajo


145

Management of annual runoff renewal as the tool for inexhaustible water use Elena Asabina

159

Water efficiency and effective water management – a shared responsibility Dagmar Bley & Günter Klein

161

International Centre for Coastal Ecohydrology – applying the Ecohydrology approach for the sustainable functioning of coastal ecosystems Luis Chícharo, Radhouan Ben-Hamadou, Ana Amaral, Pedro Range, Carmen Mateus,
David Piló, Rute Marques, Pedro Morais & Maria Alexandra Chícharo


163

Climate responsive urban groundwater management options in a stressed aquifer system H. F. Gabriel & S. Khan

166

Increasing complexity of USGS hydrological modelling: GSFLOW, a coupled groundwater and surface water flow model Jo Leslie Eimers & Steve Markstrom

169

Challenges in solving the transboundary water disputes in India under a changing climate and environment K. Shadananan Nair

171

A UNESCO Regional Centre for Integrated River Basin Management in
sub-Saharan Africa: NWRI Kaduna, Nigeria Owolabi Ajayi, Olusanjo Bamgboye & Dogara Bashir

173

Optimisation of agricultural drainage to manage irrigation salinity in Australia – an example from the Murray irrigation area, Australia Tariq Rana &
Shahbaz Khan


174

Integrated water resources management: the case of the Panama Canal Basin
Eda R. Soto

177

Utilisation des classifications d’Oldeman et de Schmidt-Ferguson pour l’aptitude culturale des sols à Batu, Indonésie Sandy Budi Wibowo

181

Water–energy nexus in irrigation supply systems using a demand-based dynamic nodal network model Aftab Ahmad, Shahbaz Khan & John Louis

183

7

Role of Knowledge Platforms for Community Engagement




Use of participatory scenario modelling as platforms in stakeholder dialogues
L. Andersson, A. Jonsson, J. Wilk & J. Alkan Olsson

187

Water 2100: A synthesis of natural and societal domains to create actionable knowledge through AquaPedia and water diplomacy Shafiqul Islam,
Yong
xuan Gao & Ali S Akanda

193

RANA-ICE, a methodology to estimate compensatory runoff in Costa Rica Anny Chaves, Alexia Pacheco, Irina Krasovskaia & Lars Gottschalk

198

Watershed prioritization for effective water resource management
Ab. Latif Ibrahim

200

Hydrological modelling in the Brazilian Water Resources Information System (SNIRH) Celso A. G. Santos, Cristiano Das N. Almeida, Amílcar Soares Júnior, Paula K. M. M. Freire & Francisco A. R. Barbosa

203

Motion charts for visualising long-term water quality in South African rivers Michael Silberbauer

205

8

From Artificial to Embodied Intelligence




Neural networks for water systems analysis: from fundamentals to complex pattern recognition Sandhya Samarasinghe

209

Water resource planning and management using motivated machine learning Janusz Starzyk

214

9

Water Allocation Dilemma




Challenges of sustainable management of the surface water resources in the Murray-Darling Basin Akhtar Abbas & Frank Walker

223

Maximising hydro-power generation within a multi-user water supply system
L. Bapela, B. Mwaka, R. Cai & H. G. Maré

226

What is a real value of water used for irrigation? Sergei Schreider &
Jonathan Plummer


228

10

Water Quality – a Critical Issue




Etude expérimentale des déformations du lit d’un canal à fond mobile: phénomène de sédimentation et erosion Cherif El Amine

233

Hydrology–climate–human health: a hydroclimatological approach to understand cholera transmission in South Asia and sub-Saharan Africa Ali S. Akanda, Antarpreet S. Jutla & Shafiqul Islam

237

Complex assessment of particle-bound radionuclide redistribution in the Plava River basin (Central European Russia) V. R. Belyaev, N. N. Ivanova, O. Evrard, M. V. Markelov, E. N. Shamshurina, P. Bonte & I. Lefevre

239

Satellite remote sensing-based forecasting of cholera outbreaks in the Bengal Delta Antarpreet S. Jutla, Ali S. Akanda & Shafiqul Islam

241

Using a multi-component indicator to identify major variables controlling the health of water resources R. Kristiana, L. C. Vilhena, G. Begg, J. P. Antenucci & J. Imberger

244

Excessive fluoride in groundwaters of River Sindhanur catchment, South India: a case study from a hard-rock sub-basin with contrasting features
Tejaswai K. Lakkundi

246

Integrated geological, geoelectrical and geochemical studies for groundwater resource evaluation in coastal areas of Sagar Island region, West Bengal, India Ranjit Kumar Majumdar & Debabrata Das

248

The wicked problem of suspended sediment profiles: a choice criterion
Mira Sabat, Abdelali Terfous, Abdellah Ghenaim & Jean Bernard Poulet

251

Simulation of wicked water migration in shallow groundwater
Seyed Reza Saghravani, Sa’ari Mustapha, Shaharin Ibrahim &
Seyed Fazlolah Saghravani


253

Large dams as purification systems for toxic PCDD/PCDF and dl-PCB congeners Magdalena Urbaniak & Maciej Zalewski

256

Climate change and water management adaptation for China Wang Xiao-Jun, Zhang Jian-Yun, Wang Guo-Qing, Liu Cui-Shan & Bao Zhen-Xin

258

11

Managing Hydrohazards




Flood hazards in Nigerian cities, the Kaduna case study A. W. Alayande &
O. A. Bamgboye

263

Groundwater flooding in Ukraine: what kind of management does it require? Oleksandr Chebanov & Iryna Konoplya

264

The role of science in solving wicked water problems – examples from groundwater management in emergency contexts Lucy Lytton & Paul Bolger

266

Influence of large water reservoir construction and filling on dynamics of Earth crust local tilts T. Matcharashvili, T. Chelidze, V. Abashidze, N. Zhukova,
E. Mepharidze & T. Kobakhidze


268

Author index

271


Hydrocomplexity: New Tools for Solving Wicked Water Problems Kovacs Colloquium, July 2010  (IAHS Publ. 338, 2010), 1-10
Tools for analysing hydrocomplexity and solving wicked water problems: a synthesis
Shahbaz Khan, Hubert Savenije, Siegfried Demuth &
Pierre Hubert

ARE WATER PROBLEMS COMPLEX AND WICKED?
Hydrocomplexity: New Tools for Solving Wicked Water Problems Kovacs Colloquium, July 2010  (IAHS Publ. 338, 2010), 13-34
Back to the basics of understanding ET
W. James Shuttleworth

Department of Hydrology & Water Resources, University of Arizona, Tucson, Arizona 8721, USA

jshuttle@hwr.arizona.edu
Abstract Hydrocomplexity occurs when hydrologists realize that improved theoretical description of a hydrological process requires the representation of controlling features that hitherto had not been considered necessary. This paper makes a critical reappraisal of currently recommended methods for estimating the water requirements of irrigated crops, which reveals there is a fundamental theoretical inconsistency between present day understanding of the interaction between plant canopies and the atmosphere as represented by the Penman-Monteith (P-M) equation, and the procedures for estimating plant water requirements currently recommended by FAO. In the P-M equation, stomatal and aerodynamic controls on the transfer processes are expressed in terms of resistances which are embedded among the meteorological controls with crop-to-crop differences expressed in terms of different values for these resistances. However, the current procedure recommended by FAO for estimating crop water represents crop-to-crop differences as a simple multiplicative crop factor applied to an estimated evaporation rate calculated by the P-M equation for a single reference crop with fixed surface resistance and aerodynamic characteristics. Recent theoretical developments that allow adoption of the more robust P-M equation description of ET for all irrigated crops are reviewed along with an example application of this new approach to estimate the water requirements in the major irrigation districts of Australia. Broader adoption into irrigation practice of this method, which is known as the Matt Shuttleworth approach, is recommended on the grounds that it is consistent with present-day understanding of the evaporation process, is feasible and simple to apply, and will facilitate future adoption of realistic representations of the effect on evapotranspiration of plant stress and of crops with partial ground cover. However, when not all the weather variables needed to calculate crop evaporation rates are available, an estimate of reference crop evaporation may still have to be made by scaling down the measured evaporation loss from an evaporation pan by a “pan factor”. In the past the value of this pan factor has been defined empirically but recent research into the physics which controls evaporation from the Class A evaporation pan has resulted in a physically-based equation that describes pan evaporation in terms of ambient climate variables. This equation, which has been verified experimentally, allows a formal definition of the pan factor that is used to investigate theoretically how ancillary measurements (or estimates) of temperature and wind speed at an evaporation pan site might be used to improve the accuracy of a pan-based estimate of reference crop evaporation.

Key words crop evaporation; pan evaporation; evapotranspiration; crop water requirements

Hydrocomplexity: New Tools for Solving Wicked Water Problems Kovacs Colloquium, July 2010  (IAHS Publ. 338, 2010), 35-36
KSOM clustering as a possible cure for the wicked water problem of inadequate data for water resources planning
ADEBAYO J. ADELOYE1 & RABEE RUSTUM2

1 School of the Built Environment, Heriot-Watt University, Edinburgh EH14 4AS, UK

a.j.adeloye@hw.ac.uk

2 College of Engineering, Dammam University, Dammam, Saudi Arabia

Hydrocomplexity: New Tools for Solving Wicked Water Problems Kovacs Colloquium, July 2010  (IAHS Publ. 338, 2010), 37-38
Mathematical modelling of water resources at the University of South Australia
John Boland

Institute for Sustainable Systems and Technologies, School of Mathematics and Statistics, University of South Australia, Australia

John.boland@unisa.edu.au

Hydrocomplexity: New Tools for Solving Wicked Water Problems Kovacs Colloquium, July 2010  (IAHS Publ. 338, 2010), 39-40
Basin water quality network design: optimum sampling sites located by information theory
JANAÍNA BEZERRA MESQUITA1 & SERGIO KOIDE2

1 STN Ed.Toscana, Bloco B, apto 205. Asa Norte, Brasília – DF. CEP 70.770-100, Brazil

jmesquita2008@gmail.com

2 Universidade de Brasília – UnB. Campus Universitário Darcy Ribeiro, Prédio SG12, Programa de Pós-Graduação em Tecnologia Ambiental e Recursos Hídricos (PTARH), Brasília – DF. CEP 79.910-900, Brazil

Hydrocomplexity: New Tools for Solving Wicked Water Problems Kovacs Colloquium, July 2010  (IAHS Publ. 338, 2010), 41-42
A national water census: quantifying, forecasting, and securing freshwater for America’s future
Matthew C. Larsen & Eric J. Evenson

US Geological Survey, 12201 Sunrise Valley Drive, Reston, Virginia 20192, USA

mclarsen@usgs.gov

Hydrocomplexity: New Tools for Solving Wicked Water Problems Kovacs Colloquium, July 2010  (IAHS Publ. 338, 2010), 43-45
Use of modern technologies in estimating unaccounted water uses in the Murray-Darling Basin, Australia
AWADHESH PRASAD

Murray-Darling Basin Authority, GPO Box 1801, Canberra 2601, Australia

awadhesh.prasad@mdba.gov.au

Hydrocomplexity: New Tools for Solving Wicked Water Problems Kovacs Colloquium, July 2010  (IAHS Publ. 338, 2010), 46-48
Yüklə 214,71 Kb.

Dostları ilə paylaş:
1   2   3   4




Verilənlər bazası müəlliflik hüququ ilə müdafiə olunur ©muhaz.org 2024
rəhbərliyinə müraciət

gir | qeydiyyatdan keç
    Ana səhifə


yükləyin