2020
DOI: 10.1021/acsami.0c17625
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Droplet Evaporation on Porous Nanochannels for High Heat Flux Dissipation

Abstract: Droplet wicking and evaporation in porous nanochannels is experimentally studied on a heated surface at temperatures ranging from 35 o C to 90 o C. The fabricated geometry consists of cross-connected nanochannels of height 728 nm with micropores of diameter 2 µm present at every channel intersection; the pores allow water from a droplet placed on the top surface to wick into the channels. Droplet volume is also varied and a total of 16 experimental cases are conducted. Wicking characteristics such as wicked di… Show more

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Cited by 21 publications
(18 citation statements)
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“…The most common mechanism of wicking in nanochannels is attributed to capillary pressure. If wicking is only driven by capillary pressure i.e., Σ P = P c ≈ 2σ cos θ/ h where σ is the surface tension, and θ is the contact angle, then eq can be simplified to the widely used Washburn equation for capillary filling: Although the linear dependence of wicking distance on t 1/2 holds at nanoscale, Washburn equation is inconsistent in predicting the experimental wicking rate. Other published literature on wicking in rectangular cross section nanochannels include a similar observation , and explained this inconsistency, primarily due to electro-viscous effect or geometrical effect. , However, these effects do not explain our observed deviation (please refer to the Supporting Information for a detailed explanation).…”
supporting
confidence: 48%
“…The most common mechanism of wicking in nanochannels is attributed to capillary pressure. If wicking is only driven by capillary pressure i.e., Σ P = P c ≈ 2σ cos θ/ h where σ is the surface tension, and θ is the contact angle, then eq can be simplified to the widely used Washburn equation for capillary filling: Although the linear dependence of wicking distance on t 1/2 holds at nanoscale, Washburn equation is inconsistent in predicting the experimental wicking rate. Other published literature on wicking in rectangular cross section nanochannels include a similar observation , and explained this inconsistency, primarily due to electro-viscous effect or geometrical effect. , However, these effects do not explain our observed deviation (please refer to the Supporting Information for a detailed explanation).…”
supporting
confidence: 48%
“…Similarly, where ε l is the emissivity of the PV panel surface (ε l ∼ 0.7) , and q tm is the heat flux removal achieved through thermal management, which is obtained by employing the porous nanochannels device (henceforth denoted as nanochannels). The nanochannels utilized in the present study offer a passive dissipation of a high heat flux through thin-film evaporation of the spray droplets dispersed over it, thus eliminating the need for a continuous supply of a coolant.…”
Section: Methodsmentioning
confidence: 99%
“…In line with that, a device with micro/nanoscale structures that can (1) continuously supply the required liquid coolant through wicking and (2) simultaneously allow a high heat removal rate at the evaporating menisci is anticipated as the best candidate to offer a promising solution to the overheating issue of the PV panel. Accordingly, we utilize the porous nanochannels device, which has demonstrated excellent wicking characteristic , as well as high heat flux dissipation through nanoscale thin-film evaporation, and numerically integrate it on the back face of a commercial PV panel to evaluate the extent of cooling. The cross-connected geometry of the buried nanochannels (height = 728 nm) offer a potential solution for a high rate of wicking, while the micropores (diameter = 2.1 μm) provided at each intersection host the sites for evaporating menisci. ,, Hence, the finding of the heat flux removal attained in such a porous nanochannels device is utilized as a technique of thermal management, and the numerical investigation of PV cooling employing an energy balance model is reported here.…”
Section: Introductionmentioning
confidence: 99%
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