To the Editor —
Zhou et al. described1 a novel plasmonic device that may be a good broadband solar absorber, but the assertion of it offering a new efficient method for desalination is problematic as the reported efficiency is more than two orders of magnitude inferior to that of off-the-shelf, affordable desalination systems in general, and vastly below even specifically solar-driven desalination systems in particular.
The desalination rate reported by Zhou and colleagues of 5.7 kg h−1 m−2 for seawater at a solar irradiance of 4 kW m−2 is equivalent to a specific energy consumption (SEC) of 702 kWh m−3. The SEC comprises a dominant — albeit not exclusive — factor in both economic and feasibility evaluations2. (It is misleading to claim that solar input is 'free', because of the substantial capital cost of all solar collection, conversion and collateral elements.)
The thermodynamic limit for desalting seawater (salt concentration of ∼35 g kg−1, at a temperature of 300 K) is 0.76 kWh m−3, although it can only be realized with work-driven processes such as reverse osmosis, and only in the reversible limit of zero flux2. The SEC reported for commercial reverse osmosis desalination plants — with pragmatic recovery ratios of ∼35–50% (recovery ratio denoting desalted water generation relative to seawater input) — is now below 3 kWh m−3, which is more than two orders of magnitude superior to the solar desalination results reported by Zhou and colleagues.
The second law of thermodynamics mandates an inherently higher SEC for thermal-driven desalination2. Indeed, available waste-heat-recovery desalination technologies at 90 °C have achieved an SEC of 190 kWh m−3 (ref. 2), which is still a factor of 3.7 better than the solar desalination system described by Zhou and colleagues. (Thermal desalination plants commonly operate at a recovery ratio of ∼35%.)
Confusion may stem from Zhou and colleagues' system being shown to efficiently deliver the heat of vaporization that, by itself, is equivalent to an SEC of ∼600 kWh m−3. (Desalination predominantly relates to a mass-transfer process with the associated change in chemical potential, and does not imply vaporization, even if vaporization is used in some thermal desalination procedures.) The fact that thermal desalination plants have achieved SEC values far below 600 kWh m−3 derives from effective heat regeneration via the use of multiple effects before any remaining unutilized heat is ultimately rejected to the environment2.
To sharpen the issue to solar-driven desalination (not necessarily thermal), consider a photovoltaic-driven reverse osmosis system. With off-the-shelf, affordable photovoltaic systems, net conversion efficiencies to alternating current electricity are now at ∼20%, with net SEC values of ∼15 kWh m−3 achievable, that is, about a factor of 47 more efficient than the solar desalination system of Zhou and colleagues.
Even if one mandates solar thermal input — replacing the waste-heat recovery noted above with input temperatures up to ∼90 °C — then with the thermal conversion efficiency of existing stationary solar collectors exceeding 60%, the net SEC can be ∼350 kWh m−3, that is, a factor of 2 better than Zhou and colleagues' solar desalination system.
There is certainly room for improvement in the economics and performance of today's commercial desalination plants2. While the idea presented by Zhou et al. might appear intriguing, the fact that its SEC values are inordinately higher than those of existing commercial plants would appear to render the notion as questionable for efficient desalination, even at the proof-of-concept level.
References
Zhou, L. et al. Nat. Photon. 10, 393–399 (2016).
Gordon, J. M. & Chua, H. T. Desalination 386, 13–18 (2016).
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Gordon, J., Chua, H. The merits of plasmonic desalination. Nature Photon 11, 70 (2017). https://doi.org/10.1038/nphoton.2017.1
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DOI: https://doi.org/10.1038/nphoton.2017.1
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