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Article

Evaluation of the Impact of Water Management Technologies on Water Savings in the Lower Chenab Canal Command Area, Indus River Basin

by
Muhammad Rizwan
1,2,*,
Allah Bakhsh
3,
Xin Li
4,5,
Lubna Anjum
3,
Kashif Jamal
1,2 and
Shanawar Hamid
6
1
Key Laboratory of Remote Sensing and Geospatial Science, Northwest Institute of Eco-Environment and Resources, Chinese Academy of Sciences, Lanzhou 730000, China
2
University of Chinese Academy of Sciences, Beijing 100049, China
3
Department of Irrigation and drainage, Faculty of Agricultural Engineering and Technology, University of Agriculture, Faisalabad 38040, Pakistan
4
Institute of Tibetan Plateau Research, Chinese Academy of Sciences, Beijing 100101, China
5
CAS Center for Excellence in Tibetan Plateau Earth Sciences, Chinese Academy of Sciences, Beijing 100101, China
6
Department of Structures and Environmental Engineering, Faculty of Agricultural Engineering and Technology, University of Agriculture, Faisalabad 38040, Pakistan
*
Author to whom correspondence should be addressed.
Water 2018, 10(6), 681; https://doi.org/10.3390/w10060681
Submission received: 20 April 2018 / Revised: 16 May 2018 / Accepted: 21 May 2018 / Published: 24 May 2018
(This article belongs to the Section Water Resources Management, Policy and Governance)
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Versions Notes

Abstract

:
Traditional irrigation practices, low crop productivity, unlevelled fields, water losses taking place during conveyance and application phases, as well as low irrigation efficiencies are the main problems of the common farmers in Pakistan. These problems are more noticeable in the command area of Lower Chenab Canal (LCC), which is the main portion of the Indus Basin Project in Pakistan. To overcome these problems, different water management technologies such as precision land levelling (PLL), bed planting, drip irrigation systems, and watercourse improvement were introduced to farmers to increase water savings and crop yields in the area of five distributaries—Khurrianwala, Shahkot, Mungi, Khikhi, Killianwala and Dijkot—during the cropping seasons of 2008 to 2015. The use of drip irrigation resulted in savings of water and fertilizer and increased the crop yields by 30–40%. Three watercourses, one on each site of 1200 m in length, were lined, which resulted in improved conveyance efficiency of 15–20%. If wheat, rice and cotton in the command area of LCC are sown on precisely levelled fields and on beds, then about 2768.1 million m3 and 3699.3 million m3 of irrigation water can be saved. These results show the potential of water-efficient technologies for saving water as well as increasing crop yields.

1. Introduction

Pakistan is one of the most water-stressed nations, with a per capita water availability of less than 1000 m3. The current proportion of agriculture towards the GDP of the country is 21%. Irrigated agriculture in the Indus Basin is the major user of water in Pakistan. About 80% of the cultivated area of Pakistan is under irrigation and about 90% of all food is produced from this area [1]. The population growth rate is very high, particularly in developing countries like Pakistan, which has placed the water supply under stress. The food requirements of this ever-increasing population demands higher food production, which will be possible through water-efficient technologies as water is the basic ingredient for irrigated agriculture. According to [2], to fulfil the food requirement for the future population, it is assessed that water diversions for irrigation should be increased up to 14–17% and food production from irrigated agriculture should be increased up to 40%.
Agriculture in Pakistan is changing rapidly and demanding more water. Irrigated agriculture is a major user of surface water and groundwater resources. Pakistan is a water-stressed country [3] and its available water resources are continuously decreasing. Water for irrigated agriculture in Pakistan is under threat because the farmers are mostly using flood irrigation to irrigate their crops to fulfil the food requirements of the ever-increasing population and wasting a huge quantity of irrigation water. Mismanagement of irrigation water is the main reason of low agricultural production. There are social as well as technical problems associated with the management of irrigation water in Pakistan. Most of the farmers are still using flood irrigation, which wastes about 50–60% of applied irrigation water. Therefore, water-efficient irrigation technologies are required to improve agricultural productivity by preserving water resources [4,5].
Water-efficient technologies such as precision land levelling, bed planting, and drip irrigation system have been introduced in many parts of the world. There is need to adopt these technologies for management and the conservation of the irrigation water in Pakistan.
According to [6], water productivity at field level can be improved by resource conservation technique (e.g., laser land levelling). According to [7], there is 2 to 3 percent increase in cultivable area in Punjab and Sind provinces of Pakistan by precision land levelling. Land levelling of cultivated area which is an imperative process in land preparation, facilitates proficient utilization of threatened water resources by eradication of needless high and low areas in field [8]. According to [9], 30% water is lost in fields due to unevenness and poor farm design. Review of existing literature on land levelling showed encouraging influence on water saving and crop productivity [10,11,12,13]. Water distribution, germination and yield of crop can be improved by effective application of precision land levelling [14]. Application efficiency of irrigation water can be improved through precision land levelling which enables even distribution of water and resulted in better crop production [15]. According to [16], about 25 to 30% of applied irrigation water can be saved through laser land levelling without affecting crop yield. According to [17], farmers can enhance their crop production by efficiently using scarce land and water resources with precision land levelling, in areas where farmers are bound to use unfit groundwater with canal water.
Bed planting, which is a proven water-efficient technique, has been tested for different crops and has given better results on cotton, wheat, maize etc. More than three million acres of cotton was under bed planting in 2003 [18]. Bed planting has shown a considerable saving of water as compared to conventional planting method and eliminating the formation of crust on the soil surface [19]. Furrow irrigation under raised bed technology saved more than 30% of irrigation water against traditional flood irrigation [20]. During the 1990s, raised bed technology was introduced for wheat in the rice-wheat areas of the Indo-Gangetic Plain following the success story of maize-wheat on permanent raised beds in Mexico [21]. The permanent raised bed technology is mainly associated with problems of water management; moreover, it diminishes the adverse influence of excess irrigation water on crop yield and/or crop irrigation in arid or semiarid regions. Many advantages of growing wheat on beds including water savings, higher yield, less lodging, better placement of fertilizer, reduced seed rate, opportunities for intercropping, and mechanical weeding [22,23,24,25,26].
Watercourses are used to convey water from canals to a farmer’s field. A large amount of water is lost in these watercourses because of high conveyance losses during its way to the farms level. Seepage, percolation, cracking, and damaging of the earthen watercourses are the main causes of poor conveyance efficiency [27]. Water losses in the improved/lined and unimproved/unlined watercourses ranged from 35–52% and 64–68%, respectively [28]. According to [29], farmers had more discharge at the inlet of their fields when conveyance losses reduced which had a significant effect on water distribution.
According to the study conducted by [30] in a water-scarce area of India, using high efficiency irrigation systems can result in a considerable amount of water savings. The study conducted by [31] on cotton seed under different irrigation methods showed that drip irrigation has significantly increased the yield of seed cotton over furrow irrigation. Initial investment for drip irrigation system is high but at the same time this system saves water and fertilizer and minimum labor and no investment is involved in land levelling [32]. According to [33], evaporation and percolation of irrigation water is reduced while crop development is improved by using drip irrigation system in which water is frequently applied to an area near the roots of plants. As compared to bed-furrow and sprinkler irrigation, water use efficiency and crop production is improved with drip irrigation system [34,35,36,37]. According to [38,39,40], use of drip irrigation system with mulching in recent years has resulted in better application of irrigation water along with fertilizers and pesticides.
To overcome the issues and problems of water insufficiency in the farmer field, the Government of Punjab through its Irrigation and Power Department, executed a mega project to improve the irrigation infrastructure and to introduce institutional reforms in irrigation and drainage subsectors in the Lower Chenab Canal (LCC) area of the Indus Basin. Along with these off-farm measures, it was also decided to incorporate an on-farm research and development component to effectively address the challenges being confronted regarding water management at farm level to achieve the potential crop yields on sustainable basis. The on-farm research and development project was executed on six distributaries (Khurrianwala, Shahkot, Dijkot, Killianwala, Mungi, and Khikhi) in the command area of LCC to introduce the water management techniques to local farmers.
The main thrust of the project was to address the issues of water management at the on-farm level by introducing water management technologies such as precision land levelling, bed planting, watercourse improvement and high efficiency irrigation system.
The objective of this study was to investigate the impact of these technologies on water savings and crop yields in the study area and to estimate the water savings in the whole command area of Lower Chenab Canal (LCC) using remote sensing (RS) and geographic information system (GIS).

2. Materials and Methods

2.1. Study Area

The current study was carried out in the command area of the Lower Chenab Canal (LCC), which is located in Rachna Doab, an area between two rivers—the Ravi and Chenab Rivers—which are tributaries of the Indus River. Rachna Doab lies in the heart of Indus Basin in Pakistan. It constitutes the single largest irrigation system in Punjab, Pakistan, with a gross command area of about 1.5 million hectares and culturable command area of 1.24 million hectares. It is one of the oldest and most developed cultivated areas in Punjab, Pakistan. The climate of the area has large seasonal variations in temperature and rainfall. The summer season is hot and lengthy, which starts in April and ends in September, with an average temperature of 35 °C, ranging from 21 °C to 49 °C. The winter season is short (December to February) and temperature varying from 5 °C to 27 °C with average temperature of 16 °C and sometimes minimum temperature falls below 0 °C during nights. The average annual rainfall in this area is around 500 mm with about 75% of annual rainfall during the monsoon season, which spans from June to September. The main crops in the area are rice, wheat, cotton, maize, sugarcane, vegetables, and fodder which are grown in two growing seasons i.e., Rabi (winter) and Kharif (summer).
The Lower Chenab Canal takes its water from River Chenab at the Khanki Head works. The main branches of LCC are the Upper Gugera (UG) Branch, the Lower Gugera (LG) Branch, the Burala Branch, the Rakh Branch, and the Jhang Branch. The project was implemented on six distributaries of Lower Chenab Canal (Figure 1) from 2008–2015. The whole area of the project was suffering from severe shortage of irrigation water supplies with marginal to low quality groundwater before start of the project.
The main thrust of the project was to introduce the following water-efficient techniques to local farmers so that more crop yield per drop of water can be achieved.
  • Precision land levelling
  • Bed planting
  • Watercourse improvement
  • High efficiency irrigation system

2.2. Precision Land Levelling (PLL)

Precision land levelling is levelling the field within certain degree of desired slope using a laser-guided beam throughout the field. It reduces evaporation and percolation losses from the field by enabling faster irrigation times and eliminating depressions and pounding of water in depressions. PLL helps to save costly farm inputs such as water and fertilizers, improve crop stand and increase crop yield as much as 15 percent. PLL has huge scope in Pakistan as most of the farmer’s field area is still irrigated by surface irrigation methods like flood irrigation, basin irrigation, border irrigation, and furrow irrigation. Application efficiency of these irrigation methods is between 30–50%. PLL is essential for these irrigation methods to escalate their application efficiency to 60–80% along with increase in crop yield.
Precision land levelling was one of the main water conservation technology and activities of the on-farm research & development component project. PLL was performed free of cost at the farmer’s field according to their land holdings. In the distributaries selected under the project, PLL was done on 2631 hectares. Water savings and increase in crop yield from field area under PLL were calculated by comparison against the field area without PLL. In every village, some fields were intentionally left where no PLL was done. During each irrigation, the irrigation time was noted and flumes were used to measure the volume of water applied to fields with and without PLL. Water saving was calculated from the total volume of irrigation water applied to fields with and without PLL. Crop yields were estimated by taking crop samples before harvesting from an area of 1 m2 from both the fields i.e., with and without PLL.

2.3. Bed Planting (BP)

Bed planting is another water saving technique, which is very beneficial on precisely levelled fields. Under the project, bed planting was demonstrated at various farmers’ fields, which were brought under precision land levelling. Before start of the project, the farmers of the area were not aware of the benefits of the bed planting. All efforts were made by project team to convince the farmers and to introduce bed planting using bed-planting machine. The bed-planting machine prepares two beds and three furrows in one pass that plants four rows for wheat or two rows for cotton and maize on each bed. The bed width is 90 cm whereas the furrow is 30 cm wide and 25.4 cm deep. There is 50% savings of irrigation water and 25% increase in crop productivity under bed planting. All fields under PLL were brought under bed planting. Water savings and increase in crop yield under bed planting were calculated by comparison against conventional planting. In each village, some fields were intentionally left without bed planting and the crop was sown using conventional methods to compare with the crop under bed planting. The geometry of bed planting for different crops is shown in Figure 2a,b.

2.4. Watercourse Improvement

In Pakistan, conveyance efficiency of the tertiary level of the irrigation system, which is watercourse, is very low and a large amount of water is lost in watercourses during its route up to the farmer’s field. Watercourse lining and earthen improvements ensure about 30–45% of irrigation water savings. The total length of 4496 m were lined on six watercourses, one on each selected distributary under the project.

2.5. Drip Irrigation System

Drip irrigation provides frequent and slow application of water to the soils through mechanical devices called emitters located at selected points along the water delivery lines i.e., lateral. In drip irrigation, the driving force of water movement is provided by an external energy source. The water is delivered through a closed-pipe system. This differs from surface irrigation technologies (flood, border, furrow and basin irrigation) in which the driving force of water flow is gravity, and the delivery and application structures (canals, ditches, furrows, small ponds and basins) are open to the atmosphere. The emitters in the drip irrigation system moistens the adjacent surface area. The percentage of the wetted surface area and soil volume depends on soil properties, initial moisture level of the soil, the applied water volume, and emitter flow rate. The drip irrigation system was one of the major activities of the project, which was installed at the project distributaries (5 acres at each distributary). Due to high initial cost of the drip irrigation system, only one drip irrigation system for row crops at each distributary of project was installed for research purposes and for demonstration to local farmers.

2.6. Crop Classification in LCC Command Area

Spatial information on different crops grown in the command area of LCC was collected from the MODIS satellite at a resolution of 250 m. Satellite images (MODIS MOD13Q1) of the LCC command area were obtained during Rabi (2007 & 2016) and Kharif (2007 & 2016) i.e., before and after the study period (Table 1). During Rabi and Kharif seasons in 2007 and 2016, extensive field visits were conducted in the villages under study to get the information about the crops grown. The coordinates recorded with GPS device in the fields in different villages of the study area were used to develop signature files of different crops grown in the study area. The satellite images obtained before and after the study period for Rabi and Kharif seasons were classified by using the developed signatures files of different crops of the study area. Image classification was carried out by supervised classification using maximum likelihood classifier in ERDAS 2014 and image processing software (ArcGIS) was used to estimate the area under different crops in LCC command.

3. Results

3.1. Land Cover/Land Use Change

The current study was conducted on six distributaries of branches of Lower Chenab Canal (LCC). Shahkot distributary and Khurrianwala distributary of Upper Gugera (UG) Branch, Mungi distributary and Khikhi distributary of Lower Gugera (LG) Branch, Killiwanwala distributary of Burala Branch and Dijkot distributary of Rakh Branch (Figure 1).
The classified LULC maps of LCC command area for Rabi 2007 & 2016 (before and after study period) and Kharif 2007 & 2016 (before and after study period) are shown in Figure 3 and Figure 4.
For Rabi season, wheat was the key crop cultivated on a massive area of all five branches of LCC, including 161,874 hectares on the Lower Gugera Branch and 283,280 hectares on the Rakh Branch with a total area of 493,716 hectares, while sugarcane was the second largest crop with total area of 117,359 hectares followed by other crops (vegetables, orchards, and forest) and fodder (Figure 5). Sugarcane was mainly cultivated in the upper parts of the Lower Gugera Branch with some disperse areas in the Rakh Branch, the Burala Branch, the Jhang Branch and the Upper Gugera Branch. For the Kharif season, other crops (mainly vegetables) were the main crops cultivated on all the branches followed by sugarcane, cotton, rice and fodder (Figure 6). The major area under cultivation of cotton was in the Burala Branch and the Lower Gugera Branch, with some scattered areas in the Jhang Branch and the Upper Gugera Branch. The acreage under rice, cotton, and sugarcane was 238,765 hectares, 80,937 hectares and 214,483 hectares respectively.
After the introduction of water-efficient technologies such as precision land levelling, bed planting and drip irrigation system in the villages under study, of six distributaries of LCC, the cultivation of wheat, cotton and vegetables have increased in the whole command of LCC (Figure 5 and Figure 6).

3.2. Precision Land Levelling (PLL)

Precision land levelling was done on an area of 2631 hectares at six distributaries selected under the project. Water savings and increase in crop yields for different crops i.e., wheat, cotton and rice from area under precision land levelling (PLL) were calculated by comparison against the area without precision land levelling. Wheat was grown at all distributaries whereas cotton was grown at Mungi, Killianwala and Khikhi distributaries. Rice was grown on only Khurrianwala and Shahkot distributaries. Comparison of yield for wheat, cotton and rice under PLL and without PLL is shown in Figure 7, whereas average water saving from precision land levelling of wheat, cotton and rice is given in Table 2, Table 3 and Table 4 respectively.
So, the total water savings from precision land levelling from villages under study was 4.3 million m3. If all the crops in the command area of LCC will be sown on laser-levelled fields, then a huge amount of irrigation water (about 2768.1 million m3) can be saved including 1384.7 million m3 from rice, 699.2 million m3 from wheat and 684.2 million m3 from cotton. Rice was mainly cultivated at the Upper Gugera and Rakh branches and cotton was mainly cultivated at the Lower Gugera and Burala branches while wheat was evenly cultivated at all five branches of the LCC. The detail is shown in Figure 8 for wheat, cotton and rice.

3.3. Bed Planting

Bed planting is a proven technology for water saving. Water can be saved efficiently from bed planted fields only if area is properly levelled. All fields under PLL were brought under bed planting. Increase in crop yields and water savings for wheat, cotton and rice under bed planting at the distributaries of the project was calculated by comparison against the conventional planting. The yield has been increased from 8% to 16.6%, 8.6% to 14.5% and 25.1% to 28.1% for wheat, cotton, and rice respectively. Yield comparison of wheat, cotton and rice at the project distributaries under bed planting and conventional planting is shown in Figure 9, whereas average water savings from bed planted field of wheat, cotton and rice is given in Table 5, Table 6 and Table 7 respectively. Total water savings from bed planting of wheat, cotton and rice at villages of study under project was 7.8 million m3. If wheat, cotton and rice in the whole command area of LCC will be sown on beds, then about 3699.3 million m3 of irrigation water can be saved including 1431.7 million m3 from wheat-planted fields, 1339.2 million m3 from rice planted fields and 928.4 million m3 from cotton planted fields (Figure 10).

3.4. Watercourse Improvement

Watercourse lining and earthen improvements ensure about 30–45% water savings. Before lining, conveyance efficiency and losses of selected watercourse at each distributary were determined by measuring discharge at different point using a cutthroat flume. The conveyance efficiency and losses of selected watercourses is given in the Table 8.
After the lining, the convey efficiency improved to more than 95% and conveyance losses reduced to minimum.

3.5. Drip Irrigation System

Drip irrigation is a much-needed technology for the near future, keeping in view the existing water shortage scenario under increasing cropping intensity and area of agriculture of the country. Drip irrigation model farms on five acres, one on each selected distributary of the project, were established and different crops were grown at these farms for dissemination purpose. The data regarding water savings and increase in crop yields from these drip irrigation systems showed that there was savings of not only water (60–80%) but also fertilizer, and a 30–40% increase in crop yield. The drip irrigation systems at Khurrianwala, Killianwala and Mungi distributaries were installed for row crop i.e., maize. Comparison of water savings and increase in crop yield for drip irrigation and bed planting during different years is shown in Table 9. The drip irrigation systems at Shahkot, Dijkot and Khikhi distributaries were installed for fruit crop i.e., Citrus. These drip systems were installed during the last year of project that’s why yield comparison at these sites could not be possible.

4. Discussion

Water scarcity is a consistent problem in the country, especially in the irrigated areas of the Lower Chenab Canal (LCC). According to [41], there is an intense scarcity of irrigation water in the command area of the LCC, which is threatening irrigated agriculture. The main cause of this problem is the mismanagement of available resources of irrigation water. This key crisis is the reason that government is focusing on management of irrigation water at farm level through different water-efficient technologies. Under the on-farm research and development project, water-efficient techniques such as precision land levelling, bed planting, and drip irrigation systems were introduced to farmers of six distributaries in the command area of the LCC.
LU/LC of different crops on the branches of the LCC has changed a lot after the promotion of water-efficient technologies. The cultivation of wheat, cotton and vegetables increased a lot especially because of promotion of precision land levelling and bed planting and drip irrigation (Table 10 and Table 11).
According to [42], the acreage under wheat and sugarcane during the Rabi season 2007–2008 was 497,214 hectares and 126,883 hectares, respectively, which was almost the same as reported in Table 8 for wheat and sugarcane. The acreage reported in Table 9 for rice, cotton, and sugarcane is in accordance with the area reported by [42] for rice, cotton and sugarcane during the Kharif season 2007 i.e., Rice cultivated area was 252,756 hectares, cotton cultivated area was 76,740 hectares and the sugarcane cultivated area was 198,419 hectares.
Precision land levelling has resulted in 22% savings of irrigation water along with 10% higher production in the rice-wheat system [8]. Precision land levelling not only curtailed the cost of operation but also helped in uniform crop stand through better application of fertilizer. The farmers of the villages under study have now become aware of the advantages of precision land levelling. They are now levelling their lands every year for irrigation water savings and better crop production. If all the crops in the command area of LCC will be sown on laser-levelled fields then about 2768 million m3 of irrigation water can be saved and used to irrigate more area.
Bed planting is another proven technology for savings of irrigation water. Bed planting is useful only on precisely levelled fields. During this study, higher water and fertilizer use efficiency was achieved in bed-planted fields. Bed planting has resulted in 30–50% savings of irrigation water and 20–25% increase in crop yield. According to [20], furrow irrigation under raised bed technology saved more than 30% of irrigation water against traditional flood irrigation. Bed planting is a new technology for the farmers of the command area of LCC. The need is to focus on this technology and 3699 million m3 of irrigation water can be saved by sowing crops on beds in the command area of LCC.
The drip irrigation system is the most efficient water-saving technology that used irrigation water, fertilizers and other nutrients the most efficiently for better crop production. The most efficient water saving technology (drip irrigation) helped small farmers of the study area to improve their livings by using agricultural inputs (water and fertilizers) more efficiently. Drip irrigation also helped the farmers to improve the quality and yield of crops especially vegetables. During the last 30–40 years, numerous efforts were made to introduce drip irrigation system in Pakistan, but no remarkable attainment were observed [43,44]. The high initial cost of drip irrigation systems impeded the adoption of it on a large scale in Baluchistan [45]. During the last few years, the government of Punjab, through its Agricultural Department, has started a project wherein drip irrigation systems are being installed on 48,562 hectares of land on a cost-sharing basis [46]. To lower the burden of the high initial cost of drip irrigation systems on farmers and to promote the adaptation of drip irrigation systems in the whole country, such projects needs to be started whereby drip irrigation systems should be installed on a cost-sharing basis.

5. Conclusions

This study was conducted in the villages where the project was successfully implemented from October 2008 to June 2015 in the command area of the Lower Chenab Canal, in the main part of Indus Basin, Pakistan.
From the findings of the seven-year study, it can be concluded that water-efficient techniques have a huge scope in the command area of the Lower Chenab Canal. The cultivated area of cotton, wheat, and other crops (vegetables and maize) is increased by about 200%, 37% and 19%, respectively, after the introduction of water-efficient irrigation techniques especially precision land levelling and bed planting. Besides the increase in crop yield, a huge amount of irrigation water (2768.1 million m3) from precision land levelling and (3699.3 million m3) from bed planting can be saved by adopting these water savings irrigation technologies in the whole command area of the Lower Chenab Canal.
On basis of the findings of this study, the water-efficient irrigation technologies—precision land levelling, bed planting, watercourse improvement, and drip irrigation—needs to be adopted for water savings and better crop yields in all of the irrigated districts in Punjab.

Author Contributions

All authors were involved in the intellectual part of this paper. X.L. and A.B. designed this research. M.R. conducted the research and wrote the manuscript. L.A. and S.H. helped in the data arrangement while K.J. helped in data analysis. X.L. helped revise the manuscript and also provided many suggestions. All the authors have read and approved the final manuscript.

Funding

This work is supported by the Strategic Priority Research Program of the Chinese Academy of Sciences (grant number XDA20100104) and the National Natural Science Foundation of China (grant Nos. 91425303 & 41630856).

Acknowledgments

The authors thanks the R&D Component of On-Farm Water Management Project, WMRC, UAF for providing relevant data.

Conflicts of Interest

The authors declare no conflict of interest. The founding sponsors had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, and in the decision to publish the results.

References

  1. Government of Pakistan. Agricultural Statistics of Pakistan 2008; Economics Division, Ministry of Food, Agriculture and Livestock, Government of Pakistan: Islamabad, Pakistan, 2008.
  2. Bos, M.G.; Burton, M.A.S.; Molden, D.J. Irrigation and Drainage Performance Assessment: Practical Guidelines; Center for Agriculture and Bioscience (CABI): Wallingford, Oxfordshire, UK, 2005. [Google Scholar]
  3. World Bank. Pakistan Country Water Resources Assistance Strategy—Water Economy: Running Dry; South Asia Region, Agriculture and Rural Development Unit Report No. 34081-PK; World Bank: Washington, DC, USA, 2005. [Google Scholar]
  4. Ambast, S.K.; Tyagi, N.; Raul, S.K. Management of declining groundwater in the Trans Indo-Gangetic Plain (India): Some options. Agric. Water Manag. 2006, 82, 279–296. [Google Scholar] [CrossRef]
  5. Qureshi, M.; Hanjra, M.A. Global water crisis and future security in an era of climate change. Food Policy 2010, 35, 365–377. [Google Scholar]
  6. Gupta, R.K.; Naresh, R.K.; Hobbs, P.R.; Jiaguo, Z.; Ladha, J.K. Sustainability of Post-Green Revolution Agriculture: The Rice–Wheat Cropping Systems of the Indo-Gangetic Plains and China. In Improving the Productivity and Sustainability of Rice–Wheat Systems: Issues and Impacts; American Society of Agronomy; Crop Science Society of America; Soil Science Society of America: Madison, WI, USA, 2003; pp. 1–25. [Google Scholar]
  7. Khan, B.M. Overview of water management in Pakistan. In Proceedings of the Regional Seminar for SAARC Member Countries on Farm Water Management, Islamabad and Lahore, Pakistan, 19–24 October 1986. [Google Scholar]
  8. Naresh, R.K.; Gupta, R.K.; Kumar, A.; Prakesh, S.; Tomar, S.S.; Singh, A.; Rathi, R.C.; Misra, A.K.; Singh, M. Impact of laser land leveler for enhancing water productivity in Western Uttar Pradesh. Int. J. Agric. Eng. 2011, 4, 133–147. [Google Scholar]
  9. Asif, M.; Ahmad, M.; Ghafoor, A.; Aslam, Z. Wheat productivity land and water use efficiency by traditional and laser land-leveling techniques. J. Biol. Sci. 2003, 3, 141–146. [Google Scholar]
  10. Jonish, J. Benefits and costs of laser land leveling in Egypt. In Proceedings of the Second International Desert Development Conference, Cairo, Egypt, 25–31 January 1987; Harwood: Geneva, Switzerland, 1987; Volume 4, pp. 6–9. [Google Scholar]
  11. Desousa, P.L.; Dedrick, A.R.; Clemmens, A.J.; Pereira, L.S. Effect of furrow elevation differences on level-basin performance. Trans. Am. Soc. Agric. Eng. 1995, 38, 153–158. [Google Scholar]
  12. Ren, W.T.; Hu, Z.F.; Cui, H.G.; Yang, C.T.; Liu, Y.; Wang, Y.J.; Zhang, Z.Y.; Li, B.F. Effect of laser-controlled land leveling and baby rice seedling direct planting on saving water. Trans. Chin. Soc. Agric. Eng. 2003, 19, 72–75. [Google Scholar]
  13. Mallappa, M.; Radder, G.D. Evaluation of Different Proportion of Levelling in Zingg Conservation Terraces on Soil Moisture Conservation, Crop Growth and Yield of Green Gram. Karnataka J. Agric. Sci. 1993, 6, 241–246. [Google Scholar]
  14. Rickman, J.F. Manual for Laser Land Leveling; Rice-wheat Consortium Technical Bulletin Series 5; Rice-wheat Consortium for the Indo-Gangetic Plains: New Delhi, India, 2002; p. 24. [Google Scholar]
  15. Jat, M.L.; Chandna, P.; Gupta, R.; Sharma, S.; Gill, M. Laser Land Levelling: A Precursor Technology for Resource Conservation; Rice-wheat Consortium for the Indo-Gangetic Plains: New Delhi, India, 2006. [Google Scholar]
  16. Bhatt, R.; Sharma, M. Laser Leveller for precision land levelling for judicious use of water in Punjab. Ext. Bull. 2009. [Google Scholar] [CrossRef]
  17. Abdullaev, I.; Hassan, M.U.; Jumaboev, K. Water saving and economic impacts of land leveling: The case study of cotton production in Tajikistan. Irrig. Drain. Syst. 2007, 21, 251–263. [Google Scholar] [CrossRef]
  18. Kahlown, M.A.; Majeed, A. Pakistan Water Resources Development and Management; Pakistan Council of Research in Water Resources: Islamabad, Pakistan, 2004. [Google Scholar]
  19. Ahmad, N.; Arshad, M.; Shahid, M.A. Bed-furrow system to replace conventional flood irrigation in Pakistan. In Proceedings of the 59th IEC Meeting and 20th ICID Conference, Lahore, Pakistan, 13–18 October 2008. [Google Scholar]
  20. Fahong, W.; Xuquing, W.; Sayre, D.K. Comparison Study on Two Different Planting Methods for Winter Wheat in China: Bed Planting Course; CIMMYT: Veracruz, Mexico, 2003. [Google Scholar]
  21. Sayre, K.D.; Hobbs, P. The Raised-Bed System of Cultivation for Irrigated Production Conditions. In Sustainable Agriculture and the Rice-Wheat System; Taylor & Francis: Abingdon, UK, 2004; pp. 337–355. [Google Scholar]
  22. Gathala, M.K.; Ladha, J.K.; Kumar, V.; Saharawat, Y.S.; Kumar, V.; Sharma, P.K.; Sharma, S.; Pathak, H. Tillage and crop establishment affects sustainability of south Asian rice-wheat system. Agron. J. 2011, 103, 961–971. [Google Scholar] [CrossRef]
  23. Connor, D.; Timsina, J.; Humphreys, E. Prospects for Permanent Beds for the Rice–Wheat System. In Improving the Productivity and Sustainability of Rice-Wheat System: Issues and Impacts’; Ladha, J.K., Buresh, R., Eds.; American Society of Agronomy; Crop Science Society of America; Soil Science Society of America: Madison, WI, USA, 2003; pp. 197–210. [Google Scholar]
  24. Bhushan, L.; Jagdish, K.L.; Gupta, R.K.; Singh, S.; Tirol-Padr, A.; Saharawata, Y.S.; Gathala, M.; Pathak, H. Saving of Water and Labor in a Rice–Wheat System with No-Tillage and Direct Seeding Technologies. Agron. J. 2007, 99, 1288–1296. [Google Scholar] [CrossRef]
  25. Ram, H. Performance of upland crops on raised beds in northwestern India. In Evaluation and Performance of Permanent Raised Bed Cropping Systems in Asia, Australia and Mexico; Australian Centre for International Agricultural Research: Canbera, Australia, 2005; pp. 41–58. [Google Scholar]
  26. Naresh, R.; Gupta, R.; Prakesh, S.; Kumar, A.; Singh4, M.; Misra, A.K. Permanent beds and rice-residue management for rice—Wheat systems in the North West India. Int. J. Agric. Sci. 2011, 7, 429–439. [Google Scholar]
  27. Ali, M. Water Conveyance Loss and Designing Conveyance System. In Practices of the Irrigation and On-Farm Water Management; Springer Science & Business Media: Berlin, Germany, 2011; pp. 1–34. [Google Scholar]
  28. Arshad, M.; Ahmad, N.; Usman, M.; Shabbir, A. Comparison of water losses between unlined and lined watercourses in Indus Basin of Pakistan. Pak. J. Agric. Sci. 2009, 46, 280–284. [Google Scholar]
  29. Sarwar, T.; Jehangir, M.; Khan, M. Effect of watercourse maintenance and variable discharges on conveyance losses and water distribution. Sarhad J. Agric. 2001, 17, 387–394. [Google Scholar]
  30. Srivastava, S.K.; Rai, B.; Kumar, S. Role of micro irrigation in improving food productivity. In Proceedings of the India Water Week: Water, Energy and Food Security, New Delhi, India, 10–14 April 2012. [Google Scholar]
  31. Muhammad, D.; Raza, I.; Ahmad, S.; Afzal, M.N.; Mian, M.A. Efficiency of drip vs furrow irrigation system with variable plant density on cotton under southern Punjab climatic conditions. Furrow 2010, 126, 2–55. [Google Scholar]
  32. Water Resources Research Institute WRRI. Pressurised Irrigation Systems and Innovative Adaptations; Water Resources Research Institute (WRRI), NARC: Islamabad, Pakistan, 2001. [Google Scholar]
  33. Chen, R.; Cheng, W.; Cui, J.; Liao, J.; Fan, H.; Zheng, Z.; Ma, F. Lateral spacing in drip-irrigated wheat: The effects on soil moisture, yield, and water use efficiency. Field Crops Res. 2015, 179, 52–62. [Google Scholar] [CrossRef]
  34. Yohannes, F.; Tadesse, T. Effect of drip and furrow irrigation and plant spacing on yield of tomato at Dire Dawa, Ethiopia. Agric. Water Manag. 1998, 35, 201–207. [Google Scholar] [CrossRef]
  35. Cetin, O. Effects of different irrigation methods on shedding and yield of cotton. Agric. Water Manag. 2002, 54, 1–15. [Google Scholar] [CrossRef]
  36. Ibragimov, N.; Evett, S.R.; Esanbekov, Y.; Kamilov, B.S.; Mirzaev, L.; Lamers, J.P.A. Water use efficiency of irrigated cotton in Uzbekistan under drip and furrow irrigation. Agric. Water Manag. 2007, 90, 112–120. [Google Scholar] [CrossRef]
  37. Hassanli, A.M.; Ebrahimizadeh, M.A.; Beecham, S. The effects of irrigation methods with effluent and irrigation scheduling on water use efficiency and corn yields in an arid region. Agric. Water Manag. 2009, 96, 93–99. [Google Scholar] [CrossRef]
  38. Qin, S.; Li, S.; Kang, S.; Du, T.; Tong, L.; Ding, R. Can the drip irrigation under film mulch reduce crop evapotranspiration and save water under the sufficient irrigation condition? Agric. Water Manag. 2016, 177, 128–137. [Google Scholar] [CrossRef]
  39. Liu, H.-J.; Wang, X.; Zhang, X.; Zhang, L.; Li, Y.; Huang, G. Evaluation on the responses of maize (Zea mays L.) growth, yield and water use efficiency to drip irrigation water under mulch condition in the Hetao irrigation District of China. Agric. Water Manag. 2016, 179, 144–157. [Google Scholar] [CrossRef]
  40. Tian, F.; Ju, Y.; Hu, H.; Liu, H. Energy balance and canopy conductance for a cotton field under film mulched drip irrigation in an arid region of northwestern China. Agric. Water Manag. 2016, 179, 110–121. [Google Scholar] [CrossRef]
  41. Shakir, A.S.; Qureshi, M.M. Crop water requirement and availability in the Lower Chenab Canal System in Pakistan. Water Resour. Manag. III WIT Trans. Ecol. Environ. 2005, 80, 10. [Google Scholar]
  42. Usman, D.M.; Liedl, R.; Shahid, M.A.; Abbas, A. Land use/land cover classification and its change detection using multi-temporal MODIS NDVI data. J. Geogr. Sci. 2015, 25, 1479–1506. [Google Scholar] [CrossRef]
  43. Latif, M. Sprinkler irrigation to harness potential benefits of water scarcity areas in Pakistan. In Proceedings of the National Seminar on Water Resources Development and Management in Arid Areas, Quetta, Pakistan, 11–12 August 1990. [Google Scholar]
  44. Yasin, M.; Ahmad, S.; Aslam, M.; Akbar, G. Adaption of pressurized irrigation in Pakistan. In Proceedings of the International Seminar on “Management of Water Resources for Sustainable Agriculture”, Lahore, Pakistan, 29–31 October 2001. [Google Scholar]
  45. Shah, S.; Malik, M.; Ali, L. Determination of the effectiveness of localized irrigation systems in Balochistan. Asian J. Plant Sci. 2002, 1, 188–189. [Google Scholar]
  46. Latif, M.; Haider, S.; Rashid, M. Adoption of High Efficiency Irrigation Systems to Overcome Scarcity of Irrigation Water in Pakistan. Proc. Pak. Acad. Sci. B Life Environ. Sci. 2016, 53, 243–252. [Google Scholar]
Water 10 00681 g001 550
Figure 1. Location of study area.
Figure 1. Location of study area.
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Figure 2. (a) Geometry of wheat lines on bed. (b) Geometry of cotton and maize on bed.
Figure 2. (a) Geometry of wheat lines on bed. (b) Geometry of cotton and maize on bed.
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Figure 3. Land use change in the Rabi Crops (A—before study period, B—after study period).
Figure 3. Land use change in the Rabi Crops (A—before study period, B—after study period).
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Figure 4. Land use change in the Kharif Crops (A—before study period, B—after study period).
Figure 4. Land use change in the Kharif Crops (A—before study period, B—after study period).
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Figure 5. Rabi crops acreage on branches of LCC.
Figure 5. Rabi crops acreage on branches of LCC.
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Figure 6. Kharif crops acreage on branches of LCC.
Figure 6. Kharif crops acreage on branches of LCC.
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Figure 7. Yield comparison of wheat, cotton and rice with and without PLL.
Figure 7. Yield comparison of wheat, cotton and rice with and without PLL.
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Figure 8. Water saving from PLL in the command area of LCC.
Figure 8. Water saving from PLL in the command area of LCC.
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Figure 9. Yield comparison of wheat, cotton and rice under BP and CP.
Figure 9. Yield comparison of wheat, cotton and rice under BP and CP.
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Figure 10. Water saving from bed planting in the command area of the LCC.
Figure 10. Water saving from bed planting in the command area of the LCC.
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Table
Table 1. Acquisition dates of satellite images (MODIS MOD13Q1).
Table 1. Acquisition dates of satellite images (MODIS MOD13Q1).
Sr. No.Date
12 February 2007
214 September 2007
32 February 2016
413 September 2016
Table
Table 2. Water savings from wheat under PLL.
Table 2. Water savings from wheat under PLL.
DistributaryTotal Irrigation Time (Hours/Hectares)Area under PLL (Hectares)Per Hectare Water Saving (m3)Total Water Saving (m3)
Without PLLPLL
Khurrianwala31.125.3607.0766.2465,083.4
Killianwala32.426.3607.0822.9499,500.3
Mungi27.122.0809.4716.5579,935.1
Khikhi25.720.9247.3823.7203,701.0
Dijkot27.322.2174.8964.7168,629.6
Shahkot23.519.1184.9613.0113,343.7
Total Water Saving = 2,030,193.1 m3
Table
Table 3. Water savings from cotton under PLL.
Table 3. Water savings from cotton under PLL.
DistributaryTotal Irrigation Time (Hours/Hectares)Area under PLL (Hectares)Per Hectare Water Saving (m3)Total Water Saving (m3)
Without PLLPLL
Killianwala61.849.4202.32519.0509,593.7
Mungi60.048.2202.32236.9452,524.9
Khikhi65.752.660.72937.2178,288.0
Total Water Saving = 1,140,406.6 m3
Table
Table 4. Water savings from rice under PLL.
Table 4. Water savings from rice under PLL.
DistributaryTotal Irrigation Time (Hours/Hectares)Area under PLL (Hectares)Per Hectare Water Saving (m3)Total Water Saving (m3)
Without PLLPLL
Khurrianwala136.3105.5161.95510.4892,133.8
Shahkot132.6103.240.55245.9212,459.0
Total Water Saving = 1,104,592.8 m3
Table
Table 5. Water savings from four irrigations of wheat under bed-planted field.
Table 5. Water savings from four irrigations of wheat under bed-planted field.
DistributaryTotal Irrigation Time (Hours/Hectare)Area under BP (Hectare)Per Hectare Water Saving (m3)Total Water Saving (m3)
Conventional PlantingBed Planting
Khurrianwala25.313.1607.02173.31,319,193.1
Killianwala26.314.4607.02116.01,284,412.0
Mungi22.012.2809.41763.31,427,215.0
Khikhi20.910.4247.31873.5463,316.6
Dijkot22.211.3174.81944.1339,828.7
Shahkot19.110.3184.91578.2291,809.2
Total Water Saving = 5,125,774.6 m3
Table
Table 6. Water savings from cotton under bed-planted fields.
Table 6. Water savings from cotton under bed-planted fields.
DistributaryTotal Irrigation Time (Hours/Hectare)Area under BP (Hectare)Per Hectare Water Saving (m3)Total Water Saving (m3)
Conventional PlantingBed Planting
Killianwala51.934.6202.33526.7713,451.4
Mungi49.433.8202.32935.9593,932.6
Khikhi51.133.360.73990.2242,205.1
Total Water Saving = 1,549,589.1 m3
Table
Table 7. Water savings from rice under bed-planted fields.
Table 7. Water savings from rice under bed-planted fields.
DistributaryTotal Irrigation Time (Hours/Hectare)Area under BP (Hectare)Per Hectare Water Saving (m3)Total Water Saving (m3)
Conventional PlantingBed Planting
Khurrianwala110.479.0161.95598.6906,413.3
Shahkot105.078.140.54805.1194,606.6
Total Water Saving = 1,101,019.9 m3
Table
Table 8. Conveyance efficiency and losses of selected watercourses.
Table 8. Conveyance efficiency and losses of selected watercourses.
Sr. No.Watercourse No.Village/Chak No.DistributaryConveyance EfficiencyConveyance Losses
128780-L441 GBKillianwala74%26%
212022-R49 RBKhurrianwala80%20%
3102190-R262 GBMongi79%21%
47996-R259 RBDijkot82%18%
580746-R331 GBKhikhi70%30%
652810-L83 RBShahkot77%23%
Table
Table 9. Water saving and yield increments of maize crop under drip irrigation.
Table 9. Water saving and yield increments of maize crop under drip irrigation.
DistributaryIrrigation MethodYearGrain Yield (kg/ha)Plant Height (cm)No. of Grains/CobIrrigation Water Depth (mm)
KhurrianwalaDrip Irrigation20136926172.4372481
20147582163.7365498
20157940167.3410473
Bed Planting20135816164.8355724
20146835152.6347767
20156842162.7382671
KillianwalaDrip Irrigation20137249177.3374487
20147782167.6362507
20158027172.5427494
Bed Planting20136637166.8349739
20146995158.5353774
20157037165.8359697
MungiDrip Irrigation20137926179.2387478
20148274180.5376482
20158549181.3400474
Bed Planting20136986170.2349747
20147269172.6350786
20157358174.1365708
Table
Table 10. Acreage (hectare) of Rabi crops on branches of the LCC.
Table 10. Acreage (hectare) of Rabi crops on branches of the LCC.
Crops Branches of LCC
LGUGBuralaRakhJhang
WheatBefore Study109,67090,65086,200123,43083,370
After Study154,190131,120146,900151,76093,480
SugarcaneBefore Study43,30010,12043,300931012,140
After Study36,83018,21033,990728020,230
FodderBefore Study34,4007280850027,1106880
After Study40502830121040501620
Other CropsBefore Study28,33035,61026,30064,75060,700
After Study61,51020,64043,71082,15048,160
Table
Table 11. Acreage (hectare) of Kharif Crops on branches of the LCC.
Table 11. Acreage (hectare) of Kharif Crops on branches of the LCC.
Crops Branches of LCC
LGUGBuralaRakhJhang
RiceBefore Study19,020109,71011,74090,65010,520
After Study17,000126,300890086,2008500
CottonBefore Study37,640567022,260121015,380
After Study149,33010,93072,03080921,040
SugarcaneBefore Study59,49018,21042,09069,61028,730
After Study49,780971030,07049,37016,590
FodderBefore Study38,85019,83038,85052,61041,280
After Study10,12024,69018,21034,40028,730
Other CropsBefore Study45,32076,08052,610108,05087,820
After Study100,36083,37063,13081,750107,240

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Rizwan, M.; Bakhsh, A.; Li, X.; Anjum, L.; Jamal, K.; Hamid, S. Evaluation of the Impact of Water Management Technologies on Water Savings in the Lower Chenab Canal Command Area, Indus River Basin. Water 2018, 10, 681. https://doi.org/10.3390/w10060681

AMA Style

Rizwan M, Bakhsh A, Li X, Anjum L, Jamal K, Hamid S. Evaluation of the Impact of Water Management Technologies on Water Savings in the Lower Chenab Canal Command Area, Indus River Basin. Water. 2018; 10(6):681. https://doi.org/10.3390/w10060681

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Rizwan, Muhammad, Allah Bakhsh, Xin Li, Lubna Anjum, Kashif Jamal, and Shanawar Hamid. 2018. "Evaluation of the Impact of Water Management Technologies on Water Savings in the Lower Chenab Canal Command Area, Indus River Basin" Water 10, no. 6: 681. https://doi.org/10.3390/w10060681

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