Abstract
Since the specific energy consumption (SEC) required for reverse osmosis (RO) desalination has been steeply reduced over the past few decades, there is an increasing demand for high-selectivity membranes. However, it is still hard to find research papers empirically dealing with increasing the salt rejection of RO membranes and addressing the SEC change possibly occurring while increasing salt rejection. Herein, we examined the feasibility of the process and material approaches to increase the salt rejection of RO membranes from the perspective of the SEC and weighed up a better approach to increase salt rejection between the two approaches. A process approach was confirmed to have some inherent limitations in terms of the trade-off between water permeability and salt rejection. Furthermore, a process approach is inappropriate to alter the intrinsic salt permeability of RO membranes, such that it should be far from a fundamental improvement in the selectivity of RO membranes. Thus, we could conclude that a material approach is necessary to make a fundamental improvement in the selectivity of RO membranes. This paper also provides discussion on the specific demands for RO membranes featuring superior mechanical properties and excellent water/salt permselectivity to minimize membrane compaction while maximizing the selectivity.
Highlights
A process approach to increase salt rejection will not allow us to overcome the trade-off between water permeability and salt rejection since the trade-off is intrinsi4 of 9 cally linked with the properties of the polyamide layer, according to empirical evidence
We explored which technical path would be more desirable to make a fundamental improvement in the selectivity of reverse osmosis (RO) membranes without compromising the competitiveness from the perspective of energy consumption
We obtained its water permeability and salt rejection by adjusting an applied pressure from 25 to 55 bar as a process approach to estimate the specific energy consumption (SEC) change occurring while varying a process parameter and qualitatively compare the degree of the SEC increase with that of the previous study via a material approach
Summary
Many countries have been struggling to reduce carbon emissions to about 50% of 1990 levels by 2030 and reach carbon neutrality by 2050, since the European Green Deal was announced [5,6]. It is necessary for humankind to reduce the amount of carbon burned for energy generation in all areas. It is the case for the industries related to water supply and water infrastructure. Many people have made continuous efforts to reduce the carbon footprint in membranebased water and wastewater treatment in various ways.
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