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Drain for Gain: Making Water Management Worth its Salt: Subsurface Drainage Practices in Irrigated Agriculture in Semi-arid and Arid Regions [Pehme köide]

  • Formaat: Paperback / softback, 224 pages, kõrgus x laius: 254x178 mm, kaal: 430 g, 20 Illustrations, color; 60 Illustrations, black and white
  • Ilmumisaeg: 18-Mar-2009
  • Kirjastus: CRC Press
  • ISBN-10: 0415498570
  • ISBN-13: 9780415498579
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Drain for Gain: Making Water Management Worth its Salt: Subsurface Drainage Practices in Irrigated Agriculture in Semi-arid and Arid RegionsSuurem pilt
  • Formaat: Paperback / softback, 224 pages, kõrgus x laius: 254x178 mm, kaal: 430 g, 20 Illustrations, color; 60 Illustrations, black and white
  • Ilmumisaeg: 18-Mar-2009
  • Kirjastus: CRC Press
  • ISBN-10: 0415498570
  • ISBN-13: 9780415498579
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780415498579.html
Märksõnad:

Salinity affects 10 to 16% of all irrigated lands while the annual rate of land loss due to waterlogging and salinity is about 0.5 million hectares per year. In this dissertation, the role of subsurface drainage to reduce these problems in irrigated agriculture in arid and semi-arid regions has been analysed and challenges for improving subsurface drainage practices have been formulated.

Although the installed subsurface drainage systems are in general technically sound and cost-effective, drainage development lags behind irrigation development and consequently a substantial part of the irrigated areas suffers from waterlogging and salinity. This is mainly because the subsurface drainage systems are designed and implemented by government, with the users, the small farmers, having little responsibility and having little input. In the adopted top-down approach the location-specific conditions and farmers’ preferences are hardly taken into consideration. Furthermore, the emphasis has been on the technical aspects (the physical infrastructure), while the organizational aspects (institutional infrastructure) have been largely neglected.

To reverse the negative trend in salt build-up and waterlogging in irrigated lands in semi-arid and arid regions, a number of challenges for enhancing the role of subsurface drainage have been formulated: (i) balancing top-down against bottom-up, (ii) from standardization to flexibility and (iii) focus on capacity development.

Preface v
Contents vii
Summary xi
Introduction
1(10)
Rationale of the Study
1(5)
Scope of the Study
6(1)
Objectives
7(1)
Hypothesis
7(1)
Methodology
8(1)
Benefits of the research
8(1)
Outline of this thesis
9(2)
Subsurface drainage practices in Egypt
11(34)
History of irrigation and drainage in Egypt
11(2)
Organization of the drainage sector
13(1)
Planning of drainage projects
14(1)
Design principles
15(2)
Installation practices
17(3)
Disposal of the drainage effluent
20(2)
A modified layout of the subsurface drainage system for rice areas
22(9)
Controlled drainage and farmers participation
31(1)
Verification of drainage design criteria in the Nile Delta
32(8)
Water balance study in a drained area
40(5)
Subsurface drainage practices in India
45(36)
History of irrigation and drainage in India
45(3)
Organization of the drainage sector
48(1)
Design principles
49(1)
Installation practices
50(1)
Disposal of the drainage effluent
51(1)
Lessons learned in famers' fields
51(13)
Water balance study in a drained area
64(2)
Participatory approach
66(2)
Participatory modelling to cope with off-site externalities of drainage
68(13)
Subsurface drainage practices in Pakistan
81(14)
History of irrigation and drainage in Pakistan
81(2)
Organization of the drainage sector
83(1)
Need for subsurface drainage
84(1)
Design principles
85(3)
Installation practices
88(2)
Participatory drainage development
90(1)
Operation and maintenance
91(1)
Disposal of the drainage effluent
91(4)
Improving subsurface drainage practices
95(22)
From manual installation to large-scale implementation
95(14)
Introduction
95(1)
Installation equipment
96(2)
Drain pipe materials
98(2)
Envelope materials
100(1)
Quality control
101(2)
Organization
103(4)
Capacity Building
107(1)
Conclusions
108(1)
The added value of research on drainage in irrigated agriculture
109(8)
Introduction
109(1)
Identification of the need for subsurface drainage
110(1)
Planning and design
111(1)
Installation
112(2)
Operation and maintenance
114(1)
Conclusions
115(2)
Capacity development to improve subsurface drainage practices
117(22)
An integrated approach for capacity development in drainage
117(11)
Introduction
117(1)
Materials and methods
118(2)
Training and dissemination of knowledge through publications
120(1)
Capacity development to improve subsurface drainage practices
121(1)
Capacity development to combat waterlogging and salinity
122(1)
Capacity development to increase farmers' participation
122(1)
Capacity development for wise use of tropical peatlands
123(2)
Discussion
125(2)
Conclusions
127(1)
Participatory research on the effectiveness of drainage
128(11)
Introduction
128(1)
Participatory research approach
129(3)
Pre-drainage investigations
132(1)
Monitoring programme
133(6)
Model simulations
139(1)
Conclusion and recommendations
139(28)
Synthesis: subsurface drainage practices in irrigated agriculture
143(7)
Are subsurface drainage systems technically sound?
143(4)
Are the subsurface drainage systems cost-effective?
147(1)
Is subsurface drainage a socially accepted practice?
148(2)
How can the integration of irrigation and drainage be improved?
150(1)
What are the main challenges in making subsurface drainage work?
151(1)
Improving subsurface drainage practices: the way forward
152(15)
The state of the art in subsurface drainage
152(2)
Institutional and policy challenges
154(2)
Increased stakeholder participation
156(5)
Drainage system requirements
161(2)
Capacity development
163(4)
The way forward: enhancing the role of subsurface drainage
167(4)
References 171(20)
Abbreviations and acronyms 191(2)
List of symbols 193(2)
Samenvatting 195(6)
Bibliography 201(6)
Curriculum vitae 207
Henk Ritzema received his MSc degree from the Department of Civil Engineering at Delft University of Technology in 1980. After graduation, he worked for the Food and Agriculture Organization of the UN and the Dutch Civil Service. In 1989 he joined the International Institute for Land Reclamation (formerly ILRI, now Alterra), Wageningen. In 2008 he joined the Irrigation and Water Engineering Group at Wageningen University.