Groundwater saving and quality improvement by reducing water footprints of crops to benchmarks levels

Karandish, Fatemeh; Hogeboom, Rick J.

doi:10.1016/j.advwatres.2018.09.011

Cited by 21 publications

(20 citation statements)

References 40 publications

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“…After all, a strategic pathway to conserve limited water resources in scarce basins is to increase water productivity in basins that still have the potential for it, e.g., by relocating crops (Pastor et al, ; Qin et al, ). One means to boost water productivity across basins is to formulate WF benchmarks for water‐using activities, i.e., a reasonable amount of water consumption per activity (Karandish et al, ). Another would be to use green water resources more productively (Schyns et al, ).…”

Section: Toward Policy Uptakementioning

confidence: 99%

Capping Human Water Footprints in the World's River Basins

et al. 2020

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Increased water demand and overexploitation of limited freshwater resources lead to water scarcity, economic downturn, and conflicts over water in many places around the world. A sensible policy measure to bridle humanity's water footprint, then, is to set local and time‐specific water footprint caps, to ensure that water appropriation for human uses remains within ecological boundaries. This study estimates—for all river basins in the world—monthly blue water flows that can be allocated to human uses, while explicitly earmarking water for nature. Addressing some implications of temporal variability, we quantify trade‐offs between potentially violating environmental flow requirements versus underutilizing available flow—a trade‐off that is particularly pronounced in basins with a high seasonal and interannual variability. We discuss several limitations and challenges that need to be overcome if setting water footprint caps is to become a practically applicable policy instrument, including the need (for policy makers) to reach agreement on which specific capping procedure to follow. We conclude by relating local and time‐specific water footprint caps to the planetary boundary for freshwater use.

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Section: Toward Policy Uptakementioning

confidence: 99%

Capping Human Water Footprints in the World's River Basins

et al. 2020

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“…EFR is estimated based on Richter et al ( 2012 ), as a constant fraction of natural runoff Hoekstra et al ( 2011 ) WF benchmark WF benchmark Minimum attainable WF in the location and time that the considered crop is grown. We obtained the climate-specific benchmark levels for the considered crops from Karandish et al ( 2018 ) Inefficient blue WF Inefficient blue water consumption occurs when the crop’s water footprint goes beyond its benchmark level Hoekstra et al ( 2011 ) Unsustainable blue WF blue WF minus blue water availability Hoekstra et al ( 2011 ) Blue water scarcity BWS It is an indicator of water scarcity which compares actual blue WF with the sustainable one. Different BWS classes are defined by Mekonnen and Hoekstra ( 2016 ), which are summarized in Table 3 Mekonnen and Hoekstra ( 2016 ) Attainable yield Y att The best yield achieved through skillful se of the best available technology under a given climate condition.…”

Section: Methodsmentioning

confidence: 99%

“…Crop’s blue water consumption is inefficient when it goes beyond its benchmark levels. We obtained the climate-specific benchmark levels for the considered crops from Karandish et al ( 2018 ). Per crop, per province, and per month, the inefficient blue WF was then determined as the difference between actual and benchmark WFs of the considered crops.…”

Section: Methodsmentioning

confidence: 99%

Socioeconomic benefits of conserving Iran’s water resources through modifying agricultural practices and water management strategies

Karandish

2021

Ambio

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Sustainable development requires modifying the current consumption pattern of natural resources. This study investigates efficient tactics for reducing the unsustainability and inefficiency of human’s food-related blue water consumption alongside improving national environmental and socioeconomic status. As a case study for Iran, 15 alternative management scenarios (AMS) were defined compared to the current on-farm management, and their effects were assessed on a monthly scale. Based on the results, 45.5 billion m3 y−1 (BCM) blue water is consumed within the croplands, 78% and 34% of which are unsustainable and inefficient, respectively. AMCs reduces the unsustainable and inefficient blue water consumption by 2–17 BCM and 2–13 BCM, respectively. The combination of yield gap closure, drip irrigation, soil mulching, and deficit irrigation has the largest effect on blue water saving; it releases or changes the status of monthly blue water scarcity in 11 provinces; increases field-employees by 132%, food security by 9%, international food-export by 87%, and gross domestic production by 54%. However, it doesn’t fully address blue water overconsumption in the summer period; hence, further measures are needed to reduce blue water scarcity to the sustainable level in these environmental hotspots.

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“…Another advantage is that these models often include possibilities to simulate the effect of alternative irrigation (irrigation scheduling and application technique) and field (mulching, tillage, bunds) management options on the WF of a crop. It is for these reasons that in recent years, crop modeling has become the new standard in WFA (Chouchane, Krol, & Hoekstra, 2018b;Chukalla, Krol, & Hoekstra, 2015, 2017Gobin et al, 2017;Hogeboom & Hoekstra, 2017;Karandish, Hoekstra, & Hogeboom, 2018;Masud, McAllister, Cordeiro, & Faramarzi, 2018;Masud, Wada, Goss, & Faramarzi, 2019;Nouri, Stokvis, Galindo, Blatchford, & Hoekstra, 2019;Zhuo, Mekonnen, Hoekstra, & Wada, 2016c). The disadvantages of crop models are the higher input data requirements and computational demands, which makes their use for high spatial resolution modeling at large geographic scales (countries, river basins, global) challenging.…”

Section: The Use Of Crop Models For Crop Water Footprint Accountingmentioning

confidence: 99%

“…So the key question is: what producers can we compare? Recent studies have grouped and compared producers that operate in similar climates (Karandish et al, 2018;Mekonnen, Hoekstra, Neale, Ray, and Yang, 2020;Zhuo, Mekonnen, and Hoekstra, 2016a) and/or on similar soils (Zhuo et al, 2016a), and by separating rainfed and irrigated agricultural systems . However, no matter what spatial scope one takes in grouping producers, within that scope there will still be variability from place to place.…”

Section: Efficiency From a Production Perspectivementioning

confidence: 99%