Spatial-temporal assessment of water footprint, water scarcity and crop water productivity in a major crop production region

Sesame (Sesamum indicum L.) is the leading oil seed crop produced in Ethiopia. It is the second most important agricultural commodity for export market in the country. It is well suited as an alternative crop production system, and it has low crop water requirement with moderate resistance to soil moisture deficit. The low land of North Western Ethiopia is the major sesame producer in the country, and the entire production is from rainfed. The rainfall distribution in North Western Ethiopia is significantly varied. This significant rainfall variability hampers the productivity of sesame. Irrigation agriculture has the potential to stabilize crop production and mitigate the negative impacts of variable rainfall. This study was proposed to identify critical growth stages during which sesame is most vulnerable to soil moisture deficit and to evaluate the crop water productivity of sesame under deficit irrigation. The performance of sesame to stage-wise and uniform deficit irrigation scheduling technique was tested at Gondar Agricultural Research Center (Metema Station), Northern Western Ethiopia. Eight treatments, four stage-wise deficit, two uniform deficit, one above optimal, and one optimal irrigation applications, were evaluated during the 2017 irrigation season. The experiment was designed as a randomized complete block design with three replications. Plant phenological variables, grain yield and crop water productivity, were used for performance evaluation. The result showed that deficit irrigation can be applied both throughout and at selected growth stages except the midseason stage. Imposing deficit during the midseason gave the lowest yield indicating the severe effect of water deficit during flowering and capsule initiation stages. When deficit irrigation is induced throughout, a 25% uniform deficit irrigation can give the highest crop water productivity with no or little yield reduction as compared with optimal irrigation. Implementing deficit irrigation scheduling technique will be beneficial for sesame production. Imposing 75% deficit at the initial, development, late season growth stages or 25% deficit irrigation throughout whole seasons will improve sesame crop water productivity.

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Impact of changing cropping pattern on the regional agricultural water productivity

The Journal of Agricultural Science ◽

10.1017/s0021859614000938 ◽

2014 ◽

Vol 153 (5) ◽

pp. 767-778 ◽

Cited By ~ 6

Author(s):

S. K. SUN ◽

P. T. WU ◽

Y. B. WANG ◽

X. N. ZHAO

Keyword(s):

Water Scarcity ◽

Crop Production ◽

Water Footprint ◽

Water Productivity ◽

Irrigation District ◽

Cropping Pattern ◽

Agricultural Water ◽

Cropping Patterns ◽

Cash Crops ◽

The Impact

SUMMARYWater scarcity is a major constraint of agricultural production in arid and semi-arid areas. In the face of future water scarcity, one possible way the agricultural sector could be adapted is to change cropping patterns and make adjustments for available water resources for irrigation. The present paper analyses the temporal evolution of cropping pattern from 1960 to 2008 in the Hetao Irrigation District (HID), China. The impact of changing cropping patterns on regional agricultural water productivity is evaluated from the water footprint (WF) perspective. Results show that the area under cash crops (e.g. sunflower and melon) has risen phenomenally over the study period because of increased economic returns pursued by farmers. Most of these cash crops have a smaller WF (high water productivity) than grain crops in HID. With the increase of area sown to cash crops, water productivity in HID increased substantially. Changing the cropping pattern has significant effects on regional crop water productivity: in this way, HID has increased the total crop production without increasing significantly the regional water consumption. The results of this case study indicate that regional agricultural water can be used effectively by properly planning crop areas and patterns under irrigation water limitations. However, there is a need to foster a cropping pattern that is multifunctional and sustainable, which can guarantee food security, enhance natural resource use and provide stable and high returns to farmers.

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Managing water resources in Libya through reducing irrigation water demand: more crop production with less water use

Libyan Studies ◽

10.1017/s0263718900009687 ◽

2013 ◽

Vol 44 ◽

pp. 95-102

Author(s):

Saad Ahmad Alghariani

Keyword(s):

Water Use ◽

Water Demand ◽

Crop Production ◽

Crop Yields ◽

Agricultural Research ◽

Water Productivity ◽

National Level ◽

Crop Water ◽

Irrigation Water Demand ◽

Crop Water Productivity

AbstractThe looming water crisis in Libya necessitates taking immediate action to reduce the agricultural water demand that consumes more than 80% of the water supplies. The available information on water use efficiency and crop water productivity reveals that this proportion can be effectively reduced while maintaining the same, if not more, total agricultural production at the national level. Crop water productivity, which is depressingly low, can be doubled through implementing several measures including relocating all major agricultural crops among different hydroclimatic zones and growth seasons; crop selection based on comparative production advantages; realisation of the maximum genetically determined crop yields; and several other measures of demand water management. There is an urgent need to establish the necessary institutional arrangements that can effectively formulate and implement these measures as guided by agricultural research and extension services incorporating all beneficiaries and stakeholders in the process.

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WATER FOOTPRINT OF CROP PRODUCTION IN TEHRAN PROVINCE

PLANNING MALAYSIA JOURNAL ◽

10.21837/pm.v17i10.634 ◽

2019 ◽

Vol 17 ◽

Author(s):

Somayeh Rezaei Kalvani ◽

Amir Hamzah Sharaai ◽

Latifah Abd Manaf ◽

Amir Hossein Hamidian

Keyword(s):

Water Consumption ◽

Water Scarcity ◽

Crop Production ◽

Agricultural Sector ◽

Water Footprint ◽

Water Productivity ◽

Blue Water ◽

Agricultural Water ◽

Severe Water Stress ◽

Tehran Province

Evaluation of supply chain of water consumption contributes toward reducing water scarcity, as it allows for increased water productivity in the agricultural sector. Water Footprint (WF) is a powerful tool for water management; it accounts for the volume of water consumption at high spatial and temporal resolution. The objective of this research is to investigate the water footprint trend of crop production in Tehran from 2008 to 2015 and to assess blue water scarcity in the agricultural sector. Water consumption of crop production was evaluated based on the WF method. Evapotranspiration was evaluated by applying the CROPWAT model. Blue water scarcity was evaluated using the blue water footprint-to-blue water availability formula. The results demonstrate that pistachio, cotton, walnut, almond, and wheat have a large WF, amounting to 11.111 m3/kg, 4,703 m3/kg, 3,932 m3/kg, 3,217 m3/kg, and 1.817 m3/kg, respectively. Agricultural blue water scarcity amounted to 0.6 (severe water stress class) (2015–2016). Agricultural water consumption in Tehran is unsustainable since it contributes to severe blue water scarcity. Tehran should reduce agricultural water scarcity by reducing the water footprint of the agricultural sector.

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Review: Climate change and the water footprint of wheat production in Zimbabwe

Water SA ◽

10.17159/wsa/2019.v45.i3.6748 ◽

2019 ◽

Vol 45 (3 July) ◽

Cited By ~ 1

Author(s):

Simbarashe Govere ◽

Justice Nyamangara ◽

Emerson Z Nyakatawa

Keyword(s):

Climate Change ◽

Crop Production ◽

Water Footprint ◽

Water Productivity ◽

Future Climate Change ◽

Climate Change Scenarios ◽

Crop Water ◽

Wheat Production ◽

Fertilization Effect ◽

Impacts Of Climate Change

Reductions in the water footprint (WF) of crop production, that is, increasing crop water productivity (CWP), is touted as a universal panacea to meet future food demands in the context of global water scarcity. However, efforts to reduce the WF of crop production may be curtailed by the effects of climate change. This study reviewed the impacts of climate change on the WF of wheat production in Zimbabwe with the aim of identifying research gaps. Results of the review revealed limited local studies on the impacts of climate change on the WF of wheat production within Zimbabwe. Despite this, relevant global and regional studies suggest that climate change will likely result in a higher WF in Zimbabwe as well as at the global and regional level. These impacts will be due to reductions in wheat yields and increases in crop water requirements due to high temperatures, despite the CO2 fertilization effect. The implications of a higher WF of wheat production under future climate change scenarios in Zimbabwe may not be sustainable given the semi-arid status of the country. The study reviewed crop-level climate change adaptation strategies that might be implemented to lower the WF of wheat production in Zimbabwe.

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Improving water use in crop production

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2007.2175 ◽

2007 ◽

Vol 363 (1491) ◽

pp. 639-658 ◽

Cited By ~ 283

Author(s):

J.I.L Morison ◽

N.R Baker ◽

P.M Mullineaux ◽

W.J Davies

Keyword(s):

Water Use ◽

Crop Production ◽

Recent Progress ◽

Physiological Responses ◽

Water Productivity ◽

Molecular Genetic ◽

Carbon Uptake ◽

Team Approach ◽

Crop Water ◽

Crop Water Productivity

Globally, agriculture accounts for 80–90% of all freshwater used by humans, and most of that is in crop production. In many areas, this water use is unsustainable; water supplies are also under pressure from other users and are being affected by climate change. Much effort is being made to reduce water use by crops and produce ‘more crop per drop’. This paper examines water use by crops, taking particularly a physiological viewpoint, examining the underlying relationships between carbon uptake, growth and water loss. Key examples of recent progress in both assessing and improving crop water productivity are described. It is clear that improvements in both agronomic and physiological understanding have led to recent increases in water productivity in some crops. We believe that there is substantial potential for further improvements owing to the progress in understanding the physiological responses of plants to water supply, and there is considerable promise within the latest molecular genetic approaches, if linked to the appropriate environmental physiology. We conclude that the interactions between plant and environment require a team approach looking across the disciplines from genes to plants to crops in their particular environments to deliver improved water productivity and contribute to sustainability.

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Physical versus economic water footprints in crop production: a spatial and temporal analysis for China

Hydrology and Earth System Sciences ◽

10.5194/hess-25-169-2021 ◽

2021 ◽

Vol 25 (1) ◽

pp. 169-191

Author(s):

Xi Yang ◽

La Zhuo ◽

Pengxuan Xie ◽

Hongrong Huang ◽

Bianbian Feng ◽

...

Keyword(s):

Value Creation ◽

Crop Production ◽

Water Productivity ◽

Economic Value ◽

Green Water ◽

Crop Water ◽

Grain Crops ◽

Crop Water Productivity ◽

Cash Crops ◽

Trade Offs

Abstract. A core goal of sustainable agricultural water resources management is to implement a lower water footprint (WF), i.e. higher water productivity, and to maximize economic benefits in crop production. However, previous studies mostly focused on crop water productivity from a single physical perspective. Little attention is paid to synergies and trade-offs between water consumption and economic value creation of crop production. Distinguishing between blue and green water composition, grain and cash crops, and irrigation and rainfed production modes in China, this study calculates the production-based WF (PWF) and derives the economic value-based WF (EWF) of 14 major crops in 31 provinces for each year over 2001–2016. The synergy evaluation index (SI) of PWF and EWF is proposed to reveal the synergies and trade-offs of crop water productivity and its economic value from the WF perspective. Results show that both the PWF and EWF of most considered crops in China decreased with the increase in crop yield and prices. The high (low) values of both the PWF and EWF of grain crops tended to cluster obviously in space and there existed a huge difference between blue and green water in economic value creation. Moreover, the SI revealed a serious incongruity between PWFs and EWFs both in grain and cash crops. Negative SI values occurred mostly in north-west China for grain crops, and overall more often and with lower values for cash crops. Unreasonable regional planting structure and crop prices resulted in this incongruity, suggesting the need to promote regional coordinated development to adjust the planting structure according to local conditions and to regulate crop prices rationally.

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WATER FOOTPRINT OF CROP PRODUCTION IN TEHRAN PROVINCE

PLANNING MALAYSIA JOURNAL ◽

10.21837/pmjournal.v17.i10.634 ◽

2019 ◽

Vol 17 (10) ◽

Author(s):

Somayeh Rezaei Kalvani ◽

Amir Hamzah Sharaai ◽

Latifah Abd Manaf ◽

Amir Hossein Hamidian

Keyword(s):

Water Consumption ◽

Water Scarcity ◽

Crop Production ◽

Agricultural Sector ◽

Water Footprint ◽

Water Productivity ◽

Blue Water ◽

Agricultural Water ◽

Severe Water Stress ◽

Tehran Province

Evaluation of supply chain of water consumption contributes toward reducing water scarcity, as it allows for increased water productivity in the agricultural sector. Water Footprint (WF) is a powerful tool for water management; it accounts for the volume of water consumption at high spatial and temporal resolution. The objective of this research is to investigate the water footprint trend of crop production in Tehran from 2008 to 2015 and to assess blue water scarcity in the agricultural sector. Water consumption of crop production was evaluated based on the WF method. Evapotranspiration was evaluated by applying the CROPWAT model. Blue water scarcity was evaluated using the blue water footprint-to-blue water availability formula. The results demonstrate that pistachio, cotton, walnut, almond, and wheat have a large WF, amounting to 11.111 m3/kg, 4,703 m3/kg, 3,932 m3/kg, 3,217 m3/kg, and 1.817 m3/kg, respectively. Agricultural blue water scarcity amounted to 0.6 (severe water stress class) (2015–2016). Agricultural water consumption in Tehran is unsustainable since it contributes to severe blue water scarcity. Tehran should reduce agricultural water scarcity by reducing the water footprint of the agricultural sector.

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