Abstract

Thermal desalination of high salinity water resources is crucial for increasing freshwater supply, but efficiency enhancements are badly needed. Nanomaterial enhancements offer enormous potential for improving promising technologies like membrane distillation (MD). However, while many approaches have been tried, such as nanoparticle solar absorbers or nanomaterial membranes, there have not been studies to directly enhance the fluid properties in MD; via nanofluids. In this work, we examine nanofluids for gap-based MD systems, including the role of nanoscale physics and system-level energy efficiency enhancements. Our model includes the dominant micro-mixing from Brownian motion in fine particle nanofluids (copper oxide) and the unusually high axial conduction from phonon resonance through Van der Waals interaction in carbon nanotube nanofluids. Carbon nanotubes resulted in consistent, wide range of improvements; while copper oxide particles showcased diminishing returns after a concentration of 0.7%, where Brownian motion effects reduced. Nanofluid characterizations illustrated uniform dispersions after at least 75 min of sonication and using surfactants to stabilize the nanoparticles through micelle formations. However, the enhancements at higher concentrations from liquid layering around nanoparticles were impractical in gap-based MD configurations, since the related high surfactant levels compromised membrane hydrophobicity and promoted fouling. Dilute solutions of metallic nanofluids can be actively integrated to enhance the performance of gap-based MD systems, whereas stronger nanofluid solutions should be limited to heat exchangers that meet their thermal energy requirements.

Thermal desalination of high salinity water resources is crucial for increasing freshwater supply, but efficiency enhancements are badly needed. Nanomaterial enhancements offer enormous potential for improving promising technologies like membrane distillation (MD). However, while many approaches have been tried, such as nanoparticle solar absorbers or nanomaterial membranes, there have not been studies to directly enhance the fluid properties in MD; via nanofluids. In this work, we examine nanofluids for gap-based MD systems, including the role of nanoscale physics and system-level energy efficiency enhancements. Our model includes the dominant micro-mixing from Brownian motion in fine particle nanofluids (copper oxide) and the unusually high axial conduction from phonon resonance through Van der Waals interaction in carbon nanotube nanofluids. Carbon nanotubes resulted in consistent, wide range of improvements; while copper oxide particles showcased diminishing returns after a concentration of 0.7%, where Brownian motion effects reduced. Nanofluid characterizations illustrated uniform dispersions after at least 75 min of sonication and using surfactants to stabilize the nanoparticles through micelle formations. However, the enhancements at higher concentrations from liquid layering around nanoparticles were impractical in gap-based MD configurations, since the related high surfactant levels compromised membrane hydrophobicity and promoted fouling. Dilute solutions of metallic nanofluids can be actively integrated to enhance the performance of gap-based MD systems, whereas stronger nanofluid solutions should be limited to heat exchangers that meet their thermal energy requirements.

Comments

This is the author-accepted manuscript of .Parmar, H.B., Juybari, H.F., Yogi, Y.S., Nejati, S., Jacob, R.M., Menon, P.S. and Warsinger, D.M., 2021. Nanofluids improve energy efficiency of membrane distillation. *Nano Energy*, *88*, p.106235. Copyright Elsevier, it is made available here CC-BY-NC-ND, and the version of record is available at DOI: 10.1016/j.nanoen.2021.106235.

Keywords

Nanofuids, Membranedistillation, Thermaldesalination, Carbonnanotubes, Copperoxide, Brownian motion

Date of this Version

10-2021

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