Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-28T01:06:22.651Z Has data issue: false hasContentIssue false
  • English
  • Français

Solar desalination for sustainable brackish water management in arid land agriculture

Published online by Cambridge University Press:  21 March 2013

Andrea Ghermandi ,
Rami Messalem ,
Rivka Offenbach  and
Shabtai Cohen
Andrea Ghermandi*
Affiliation:
Zuckerberg Institute for Water Research, Desalination and Water Treatment, Ben-Gurion University of the Negev, Beer-Sheva 84105, Israel Graduate School of Management, Natural Resources and Environmental Management, University of Haifa, Haifa 31905, Israel
Rami Messalem
Affiliation:
Zuckerberg Institute for Water Research, Desalination and Water Treatment, Ben-Gurion University of the Negev, Beer-Sheva 84105, Israel
Rivka Offenbach
Affiliation:
Central and Northern Arava Research and Development, M.P. Arava, Sapir, Israel
Shabtai Cohen
Affiliation:
Central and Northern Arava Research and Development, M.P. Arava, Sapir, Israel
*
*Corresponding author: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

An agricultural facility aimed at sustainable production of crops in arid environments was built and tested in Hatzeva, Israel. The facility relies on solar-powered desalination with nanofiltration membranes to treat the local brackish water (EC=2.32 dS m−1) and produce high-quality irrigation water (EC=0.71 dS m−1). Red beet, a salt-tolerant crop, was grown with the concentrate stream (EC=4.73 dS m−1), eliminating the need for concentrate disposal and with potential net economic benefits. Agricultural experiments with variable irrigation water quality, application rate, and four staple crops (potato, maize, millet and sorghum) were conducted over two growing seasons between September 2010 and June 2011. The desalination plant operated at low pressure (4.3 bar) and energy consumption (1.37 kWh m−3) and with little maintenance over the entire study period. The results of the agricultural experiments consistently showed that irrigation with desalinated water promoted more efficient use of resources such as water and inorganic fertilizers. A reduction of 25% in the irrigation rate and use of fertilizers compared with best-practice guidelines was achieved with desalinated water, with no detectable detrimental effect on the marketable yield. On the contrary, a statistically significant yield increase was observed for sorghum (+10%). An increase in water productivity with desalinated water was observed for all four staple crops.

Keywords

arid agriculturebrackish water agriculturedesalinationnanofiltration membranesrenewable energy
Type
Preliminary Report
Information
Renewable Agriculture and Food Systems , Volume 29 , Issue 3: Special Section: Themed Content: Integrated Crop-Livestock Systems , September 2014 , pp. 255 - 264
Copyright
Copyright © Cambridge University Press 2013 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1Beddington, J., Asaduzzaman, M., Clark, M., Fernandez, A., Guillou, M., Jahn, M., Erda, L., Mamo, T., Van Bo, M., Nobre, C., Scholes, R., Sharma, R., and Wakhungu, J. 2012. Achieving Food Security in the Face of Climate Change: Final Report from the Commission on Sustainable Agriculture and Climate Change. CGIAR Research Program on Climate Change, Agriculture and Food Security. Copenhagen, Denmark.Google Scholar
2World Bank. 2008. Brief on Agriculture and Rural Development in Middle East and North Africa. Available at Web site http://siteresources.worldbank.org/INTMENAREGTOPAGRI/Resources/AGRICULTURE-ENG-2008AM.pdf (verified December 2012).Google Scholar
3Tanwar, B.S. (ed.) 2003. Saline Water Management for Irrigation. International Commission on Irrigation and Drainage (ICID), New Delhi, India.Google Scholar
4Qadir, M., Sharma, B., Bruggeman, A., Choukr-Allah, R., and Karajeh, F. 2007. Non-conventional water resources and opportunities for water augmentation to achieve food security in water scarce countries. Agricultural Water Management 87:222.Google Scholar
5Hamdy, A. 2002. Saline irrigation management for a sustainable use. In Hamdy, A., Katerji, N., Van Horn, J.W., and Mastrorilli, R. (eds). Mediterranean Crop Responses to Water and Soil Salinity: Ecophysiological and Agronomical Analysis. Options Méditerranéennes Série B, CIHEAM, Bari, Italy. p. 185230.Google Scholar
6Ayars, J.E. 2011. On-farm irrigation and drainage practices. In Wallender, W.W. and Tanji, K. (eds). Agricultural Salinity Assessment and Management. ASCE manual and reports on engineering practices, 2nd ed. American Society of Civil Engineers, Reston, VA, USA.Google Scholar
7Sharma, B. and Minhas, P. 2005. Strategies for managing saline/alkali waters for sustainable agricultural production in South Asia. Agricultural Water Management 78:136151.Google Scholar
8Ben-Gal, A., Ityel, E., Dudley, L., Cohen, S., Yermiyahu, U., Presnov, E., Zigmond, L., and Shani, U. 2008. Effect of irrigation water salinity on transpiration and on leaching requirements: A case study for bell peppers. Agricultural Water Management 95:587597.Google Scholar
9Sadeh, A. and Ravina, I. 2000. Relationships between yield and irrigation with low-quality water—a system approach. Agricultural Systems 64:99113.Google Scholar
10Ghermandi, A. and Messalem, R. 2009. The advantages of NF desalination of brackish water for sustainable irrigation: The case of the Arava Valley in Israel. Desalination and Water Treatment 10:101107.Google Scholar
11Yermiyahu, U., Tal, A., Ben-Gal, A., Bar-Tal, A., Tarchitzky, J., and Lahav, O. 2007. Rethinking desalinated water quality and agriculture. Science 318:920921.Google Scholar
12Ayers, R.S. and Westcot, D.W. 1985. Water Quality for Agriculture. Food and Agriculture Organization of the United Nations (FAO). Irrigation and drainage paper 29, Rome, Italy.Google Scholar
13Ghermandi, A. and Messalem, R. 2009. Solar-driven desalination with reverse osmosis: The state of the art. Desalination and Water Treatment 7:285296.Google Scholar
14Chaibi, M. 2000. An overview of solar desalination for domestic and agriculture water needs in remote arid areas. Desalination 127:119133.Google Scholar
15Papapetrou, M., Wieghaus, M., and Biercamp, C. 2010. Roadmap for the Development of Desalination Powered by Renewable Energy. Fraunhofer Verlag, Stuttgart, Germany.Google Scholar
16Glueckstern, P. and Priel, M. 1997. Optimized brackish water desalination plants with minimum impact on the environment. Desalination 108:1926.Google Scholar
17Ahmed, M., Arakel, A., Hoey, D., Thumarukudy, M.R., Goosen, M.F.A., Al-Haddabi, M., and Al-Belushi, A. 2003. Feasibility of salt production from inland RO desalination plant reject brine: A case study. Desalination 158:109117.CrossRefGoogle Scholar
18Oren, Y., Korngold, E., Daltrophe, N., Messalem, R., Volkman, Y., Aronov, L., Weismann, M., Bouriakov, N., Glueckstern, P., and Gilron, J. 2010. Pilot studies on high recovery BWRO-EDR for near zero liquid discharge approach. Desalination 261:321330.Google Scholar
19Riley, J.J., Fitzsimmons, K.M., and Glenn, E.P. 1997. Halophyte irrigation: An overlooked strategy for management of membrane filtration concentrate. Desalination 110:197211.Google Scholar
20Ladewig, B. and Asquith, B. 2011. Desalination Concentrate Management. Springer, Heidelberg, Germany.Google Scholar
21Ventura, Y., Wuddineh, W.A., Shpigel, M., Samocha, T.M., Klim, B.C., Cohen, S., Shemer, Z., Santos, R., and Sagi, M. 2011. Effects of day length on flowering and yield production of Salicornia and Sarcocornia species. Scientia Horticulturae 130:510516.CrossRefGoogle Scholar
22Pasternak, D., De Malach, Y., and Borovic, I. 1985. Irrigation with brackish water under desert conditions II. Physiological and yield response of maize (Zea mays) to continuous irrigation with brackish water and to alternating brackish-fresh-brackish water irrigation. Agricultural Water Management 10:4760.Google Scholar
23Pasternak, D., Sagih, M., DeMalach, Y., Keren, Y., and Shaffer, A. 1995. Irrigation with brackish water under desert conditions XI. Salt tolerance in sweet-corn cultivars. Agricultural Water Management 28:325334.Google Scholar
24Bustan, A., Sagi, M., Malach, Y.D., and Pasternak, D. 2004. Effects of saline irrigation water and heat waves on potato production in an arid environment. Field Crops Research 90:275285.Google Scholar
25Levy, D. 1992. The response of potatoes (Solanum tuberosum L.) to salinity: Plant growth and tuber yields in the arid desert of Israel. Annals of Applied Biology 120:547555.CrossRefGoogle Scholar
26Maas, E.V. and Hoffman, G.J. 1977. Crop salt tolerance: Current assessment. Journal of the Irrigation and Drainage Division 103:115134.Google Scholar