1. Al-Qaraghuli A, Kazmerski LL. Comparison of Technical and Economic Performance of the main Desalination Processes with and without Renewable Energy Coupling. Proceedings of the American Solar Energy Society World Renewable Energy Forum. 2012;1–8. This paper provides a clear overall view of various systems in terms of requirements, such as energy consumption, and performance, such as cost of treated water.

2. Peñate B, Castellano F, Bello A, García-Rodríguez L. Assessment of a stand-alone gradual capacity reverse osmosis desalination plant to adapt to wind power availability: a case study. Energy. 2011;36(7):4372–84. This paper clearly explains the challenges of synchronizing desalination with wind availability..

3. Park GL, Schäfer AI, Richards BS. Renewable energy powered membrane technology: the effect of wind speed fluctuations on the performance of a wind-powered membrane system for brackish water desalination. J Membr Sci. 2011;370(1–2):34–44. This paper provides great detail about the impact of intermittence on the desalination process..

4. Park GL, Richards BS, Schäfer AI. The effect of intermittent operation on a wind-powered membrane system for brackish water desalination. Water Sci Technol. 2012;65(5):867–74.

5. Park GL, Schäfer AI, Richards BS. Renewable energy-powered membrane technology: supercapacitors for buffering resource fluctuations in a wind-powered membrane system for brackish water desalination. Renew Energy. 2013;50:126–35. This paper makes a very good case for the use of supercapacitors to mitigate intermittence..