Your search found 14 records
1 Ghassemi, F.; Jakeman, A. J.; Thomas, G. A. 1989. Ground-water modeling for salinity management: An Australian case study. Water Resources Journal, 163:72-78.
(Location: IWMI-HQ Call no: PER Record No: H06297)
2 Mahendrarajah, S.; Warr, P. G.; Jakeman, A. J.. 1992. Optimal extraction of small-scale surface water storage in Asia. Water Resources Research, 28(5):1207-1219.
(Location: IWMI-HQ Call no: PER Record No: H010636)
3 Ghassemi, F.; Jakeman, A. J.; Nix, H. A. 1995. Salinisation of land and water resources: Human causes, extent, management and case studies. Canberra, Australia: Centre for Resource and Environmental Studies. xviii, 526p.
Soil salinity ; Sodic soils ; Mathematical models ; Water resources ; Irrigation systems ; Irrigation efficiency ; Water quality ; Environmental effects ; Surface drainage ; Subsurface drainage ; Conjunctive use ; Remote sensing ; Mapping ; Soil degradation ; Crops ; Water requirements ; Water costs ; Conflict ; River basins ; Case studies ; Groundwater ; Waterlogging / Argentina / Australia / China / Egypt / India / Iran / Pakistan / South Africa / Thailand / USA
(Location: IWMI-HQ Call no: 631.7.5 G000 GHA Record No: H016533)
4 Ghassemi, F.; Jakeman, A. J.; Nix, H. A. 1995. Avoiding disasters: The role of systems analysis and an integrated approach in water resources development. GeoJournal, 35.1:49-51.
Water resources development ; Land management ; Salinity ; Drainage ; Systems analysis ; Disasters / Australia / Egypt / China / Pakistan / USA / India / Russian Federation
(Location: IWMI-HQ Call no: P 4987 Record No: H023745)
5 Jakeman, A. J.; Green, T. R.; Zhang, L.; Beavis, S. G.; Evans, J. P.; Dietrich, C. R.; Barnes, B. 1998. Modelling catchment erosion, sediment and nutrient transport in large basins. In de Vries, F. W. T. P.; Agus, F.; Kerr, J. (Eds.). Soil erosion at multiple scales: Principles and methods for assessing causes and impacts. Wallingford, UK: CABI; Bangkok, Thailand: IBSRAM. pp.343-355.
Catchment areas ; Erosion ; Sedimentation ; Simulation models ; Rainfall-runoff relationships ; Stream flow ; Climate / Australia / Thailand / New South Wales / Namoi Basin / Ping Basin
(Location: IWMI-HQ Call no: 631.45 G000 DEV Record No: H027846)
6 Schreider, S. Y.; Jakeman, A. J.. 1999. Surface runoff modelling in ungauged subcatchments of the Mae Chaem Catchment, Northern Thailand: Part I, methodology. In Oxley, L.; Scrimgeour, F. (Eds.), MODSIM 99 û International Congress on Modelling and Simulation: Modelling the dynamics of natural, agricultural, tourism and socio- economic systems. Proceedings, Volume 1, University of Waikato, Hamilton, New Zealand, 6th-9th December 1999. Canberra, Australia: Modelling and Simulation Society of Australia and New Zealand Inc. pp.81-86.
Surface runoff ; Simulation models ; Irrigated farming ; Catchment areas ; Stream flow / Thailand / Mae Chaem Catchment
(Location: IWMI-HQ Call no: 003.3 G000 OXL Record No: H030413)
7 Schreider, S. Y.; Gallant, J.; Jakeman, A. J.; Merritt, W. S. 1999. Surface runoff modeling in ungauged subcatchments of the Mae Chaem Catchment, Northern Thailand: Part II, first pass approach. In Oxley, L.; Scrimgeour, F. (Eds.), MODSIM 99 û International Congress on Modelling and Simulation: Modelling the dynamics of natural, agricultural, tourism and socio- economic systems. Proceedings, Volume 1, University of Waikato Hamilton, New Zealand, 6th-9th December 1999. Canberra, Australia: Modelling and Simulation Society of Australia and New Zealand Inc. pp.87-92.
Surface runoff ; Stream flow ; Simulation models ; Catchment areas ; Irrigated farming ; Paddy fields ; Rice ; Land use / Thailand / Mae Chaem Catchment
(Location: IWMI-HQ Call no: 003.3 G000 OXL Record No: H030414)
8 Evans, J. P.; Jakeman, A. J.. 1997. Development of a simple, catchment-scale, rainfall-evapotranspiration-runoff model. In McDonald, A. D.; McAleer, M. (Eds.), MODSIM 97 - International Congress on Modelling and Simulation, University of Tasmania, Hobart, 8-11 December 1997: Proceedings. Vol.1. Canberra, Australia: Modelling and Simulation Society of Australia and New Zealand Inc. pp.222-227.
(Location: IWMI-HQ Call no: 003.3 G000 MCD Record No: H030511)
9 Jakeman, A. J.; Saowapon, C.; Jintrawet, A.; Trisophon, K.; Evans, J.; Wong, F. 1997. Biophysical component of an integrated water resources assessment project in the Upper Chao Phraya headwaters, Northern Thailand. In McDonald, A. D.; McAleer, M. (Eds.), MODSIM 97 - International Congress on Modelling and Simulation, University of Tasmania, Hobart, 8-11 December 1997: Proceedings: Vol.2. Canberra, Australia: Modelling and Simulation Society of Australia and New Zealand Inc. pp.687-691.
River basins ; Water resource management ; Simulation ; Erosion ; Water quality ; Soil degradation ; Sedimentation ; Models / Thailand / Upper Chao Phraya / Ping Basin
(Location: IWMI-HQ Call no: 003.3 G000 MCD Record No: H030520)
10 Mackey, B.; Trisophon, K.; Ekasingh, M.; Sangawongse, S.; Wong, F.; Jakeman, A. J.. 1997. A decision support system for integrated water resources assessment and management: A case study of the Upper Chao Phraya headwaters, Northern Thailand. In McDonald, A. D.; McAleer, M. (Eds.), MODSIM 97 -International Congress on Modelling and Simulation, University of Tasmania, Hobart, 8-11 December 1997: Proceedings: Vol.2. Canberra, Australia: Modelling and Simulation Society of Australia and New Zealand Inc. pp.704-709.
River basins ; Catchment areas ; Water resource management ; Assessment ; Decision support tools ; Models ; Case studies / Thailand / Upper Chao Phraya / Ping Basin
(Location: IWMI-HQ Call no: 003.3 G000 MCD Record No: H030522)
11 Schreider, S. Y.; Jakeman, A. J.; Letcher, R. A.; Nathan, R. J.; Neal, B. P.; Beavis, S. G. 2002. Detecting changes in streamflow response to changes in non-climate catchment conditions: Farm dam development in the Murray–Darling Basin, Australia. Journal of Hydrology, 262:84-98.
Stream flow ; Rainfall-runoff relationships ; Models ; Land use ; Hydrology ; Dams ; Catchment areas / Australia / Murray Darling Basin / Jamieson River / Yass River / Broadwater Creek
(Location: IWMI-HQ Call no: P 6569 Record No: H033039)
12 Jakeman, A. J.; Letcher, R. A.; Rojanasoonthon, S.; Cuddy, S. (Eds.) 2005. Integrating knowledge for river basin management: Progress in Thailand. Canberra, Australia: ACIAR. 223p.
River basins ; Water resource management ; Catchment areas ; Natural resources ; Water use ; Land management ; Decision support tools / Thailand
(Location: IWMI-HQ Call no: 333.91 G750 JAK Record No: H037726)
13 Iwanaga, T.; Partington, D.; Ticehurst, J.; Croke, B. F. W.; Jakeman, A. J.. 2020. A socio-environmental model for exploring sustainable water management futures: participatory and collaborative modelling in the Lower Campaspe Catchment. Journal of Hydrology: Regional Studies, 28:100669. (Online first) [doi: https://doi.org/10.1016/j.ejrh.2020.100669]
Water management ; Models ; Sustainability ; Participatory approaches ; Environmental effects ; Water policy ; Water use ; Water allocation ; Surface water ; Groundwater ; Indicators ; Rain ; Ecology ; Catchment areas ; Pumping ; Farmers ; Stakeholders / Australia / Lower Campaspe / Campaspe River
(Location: IWMI HQ Call no: e-copy only Record No: H049525)
https://www.sciencedirect.com/science/article/pii/S2214581819303726/pdfft?md5=64888198b853ccec18d3f41d072748ab&pid=1-s2.0-S2214581819303726-main.pdf
https://vlibrary.iwmi.org/pdf/H049525.pdf
https://vlibrary.iwmi.org/pdf/H049525.pdf
(14.80 MB) (14.80 MB)
Study region: Lower Campaspe, North Central Victoria, Australia
Study focus: This paper presents a component-based integrated environmental model developed through participatory processes to explore sustainable water management options. Possible futures with improved farm profitability and ecological outcomes relative to modelled baselines were identified through exploratory modelling. The integrated model and the results produced are intended to raise awareness and facilitate discussion with and amongst stakeholders.
New hydrological insights: The modelling illustrates that improved farm level knowledge and management with regard to crop water requirements, soil water capacity, and irrigations are the most significant factors towards achieving outcomes that are robust to a range of climate and water policy futures. Assuming farmer management with regard to these factors are at their most optimal, increasing irrigation efficiency alone did not lead to improved farm profitability and ecological outcomes under drier climate conditions. Likelihood of achieving robust outcomes were further improved through the conjunctive use of surface and groundwater, with increased consideration of groundwater use a key factor. Further discussion on the viability and impact of increased groundwater use and conjunctive use policies should be further considered.
Study focus: This paper presents a component-based integrated environmental model developed through participatory processes to explore sustainable water management options. Possible futures with improved farm profitability and ecological outcomes relative to modelled baselines were identified through exploratory modelling. The integrated model and the results produced are intended to raise awareness and facilitate discussion with and amongst stakeholders.
New hydrological insights: The modelling illustrates that improved farm level knowledge and management with regard to crop water requirements, soil water capacity, and irrigations are the most significant factors towards achieving outcomes that are robust to a range of climate and water policy futures. Assuming farmer management with regard to these factors are at their most optimal, increasing irrigation efficiency alone did not lead to improved farm profitability and ecological outcomes under drier climate conditions. Likelihood of achieving robust outcomes were further improved through the conjunctive use of surface and groundwater, with increased consideration of groundwater use a key factor. Further discussion on the viability and impact of increased groundwater use and conjunctive use policies should be further considered.
14 Packett, E.; Grigg, N. J.; Wu, J.; Cuddy, S. M.; Wallbrink, P. J.; Jakeman, A. J.. 2020. Mainstreaming gender into water management modelling processes. Environmental Modelling and Software, 127:104683 (Online first). [doi: https://doi.org/10.1016/j.envsoft.2020.104683]
Water management ; Modelling ; Gender mainstreaming ; Integrated management ; Water resources ; Sustainable Development Goals ; Gender equality ; Equity ; Decision making ; Stakeholders ; Policies
(Location: IWMI HQ Call no: e-copy only Record No: H049569)
https://www.sciencedirect.com/science/article/pii/S1364815219306966/pdfft?md5=9bbd07f9dad094b7d69d4f78e41cc5ec&pid=1-s2.0-S1364815219306966-main.pdf
https://vlibrary.iwmi.org/pdf/H049569.pdf
https://vlibrary.iwmi.org/pdf/H049569.pdf
(0.51 MB) (524 KB)
Although the Dublin principles of Integrated Water Resource Management (IWRM) are well-established, the third principle on gender is commonly missing in practice. We use gender mainstreaming to identify examples where gender-specific perspectives might influence water resource management modelling choices. We show how gender considerations could lead to different choices in all modelling phases, providing examples from three familiar components of modelling practice: (a) problem framing and conceptualization, (b) model construction, documentation and evaluation and (c) model interpretation and decision support. We suggest a future approach for integrating gender perspectives in modelling. Including gender dimensions could strengthen modelling results by engaging with a range of stakeholders and highlighting questions, knowledge, values and choices that may otherwise be overlooked. Such an approach won't always result in a different model and results. At the very least it's a mechanism to explore and reveal gendered assumptions knowingly, or unknowingly, embedded into the model.
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