Mechanism Interaction During Droplet Evaporation on Nanostructured Hydrophilic Surfaces

Carey, Van P.; Wemp, Claire K.; McClure, Emma R.; Cabrera, Samuel

doi:10.1115/imece2018-87991

Cited by 3 publications

(4 citation statements)

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“…A combination of the fast velocity of the bubble released by the nucleation sites and the liquid capillary pumping can prevent the formation of a stable continuous vapor layer. The occurrence of evaporation regime on the NW surface at higher superheat (as shown in Figures S16 and S17) could be explained by the delay of the onset of nucleate boiling on nanostructured hydrophilic surfaces (as reported by Van Carey et al (2018)). Indeed, nanocavities require larger superheat to be activated as shown in Figure a.…”

Section: Resultssupporting

confidence: 57%

Can Wicking Control Droplet Cooling?

Auliano

Fernandino

et al. 2019

Langmuir

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Wicking, defined as absorption and passive spreading of liquid into a porous medium, has been identified as a key mechanism to enhance the heat transfer and prevent the thermal crisis. Reducing the evaporation time and increasing the Leidenfrost point (LFP) are important for an efficient and safe design of thermal management applications, such as electronics, nuclear, and aeronautics industry. Here, we report the effect of the wicking of superhydrophilic nanowires (NWs) on the droplet vaporization from low temperatures to temperatures above the Leidenfrost transition. By tuning the wicking capability of the surface, we show that the most wickable NW results in the fastest evaporation time (reduction of 82, 76, and 68% compared with a bare surface at, respectively, 51, 69, and 92 °C) and in one of the highest shifts of the LFP of a water droplet (5 μL) in the literature (about 260 °C).

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Section: Resultssupporting

confidence: 57%

Can Wicking Control Droplet Cooling?

Auliano

Fernandino

et al. 2019

Langmuir

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“…According to Fourier’s law, the temperature drop across the layer was calculated as the layer thickness multiplied by the heat flux, divided by the thermal conductivity where q ″ is the heat flux, k is the thermal conductivity, d T is the temperature drop, and d x is the layer thickness. Temperature drop increases with heat flux, therefore 200 W/cm 2 , previously determined to be the critical heat flux of the nanostructured surface was used to calculate the temperature drop across the ZnO coating and also the mineral deposition layer. The nanoporous layer was approximated as a 5 μm thick solid ZnO layer with thermal conductivity of 23.399 W/mK .…”

Section: Results and Discussionmentioning

confidence: 99%

“…The nanoporous nature of the surface coating caused the surface to have extremely low contact angles and enhanced rewetting of dry areas. 19,20 Droplet evaporation on the nanostructured surface was found to provide higher heat fluxes than evaporation on a plain copper surface at all superheats with a CHF twice as high as the uncoated copper. 20 Although not the focus of this durability study, similar ZnO nanopillars have also been shown to have desirable antimicrobial characteristics which would prevent biofouling in potential heat exchangers.…”

Section: ■ Introductionmentioning

confidence: 95%

“…Previous experiments have demonstrated improved droplet spreading on the nanostructured surface and subsequent enhancement of vaporization performance. The nanoporous nature of the surface coating caused the surface to have extremely low contact angles and enhanced rewetting of dry areas. , Droplet evaporation on the nanostructured surface was found to provide higher heat fluxes than evaporation on a plain copper surface at all superheats with a CHF twice as high as the uncoated copper . Although not the focus of this durability study, similar ZnO nanopillars have also been shown to have desirable antimicrobial characteristics which would prevent biofouling in potential heat exchangers. − In order to assess the durability of the ZnO nanostructure, this study focuses on the comparison of clean nanostructured surfaces and the same surfaces after artificially hardened water has been used to replicate accelerated fouling of the surface due to evaporation of hard water.…”

Section: Introductionmentioning

confidence: 99%

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Nanoscale and Macroscale Effects of Mineral Deposition During Water Evaporation on Nanoporous Surfaces

McClure

Carey

2020

ACS Appl. Mater. Interfaces

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Recent studies have indicated that droplet evaporation heat transfer can be substantially enhanced by fabricating a thin nanoporous superhydrophilic layer on a metal substrate. Such surfaces have immense potential to improve spray cooling processes, however, little durability testing of the surface has been performed. In spray cooling applications, as water evaporates any impurities in the water will be deposited onto the surface. Primarily, this investigation serves to demonstrate how minerals in hard water deposit on the surface and interact with the ZnO nanopillars of the superhydrophilic surface. Quantifying the effects of mineral scale on droplet spreading and vaporization heat transfer on the surface is important in determining implementation requirements to advance the surface into industry applications. Micrographs of the surface demonstrate minerals deposit nonuniformly and quickly fill the nanostructure. Despite a reduction in the extent of droplet spreading due to the mineral deposition, scaled surfaces still demonstrated improved thermal performance compared to an uncoated, smooth copper surface. Scale tended to build up on previously deposited scale, leaving largely uncoated areas where droplets chose to preferentially spread and resulting in a continued low contact angle. Maintaining these uncoated areas and reducing the contaminants present in the water will extend the life and performance of the nanostructured surface.

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Heat transport for evaporating droplets on superhydrophilic, thin, nanoporous layers

Wemp

Carey

2019

International Journal of Heat and Mass Transfer

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Mechanism Interaction During Droplet Evaporation on Nanostructured Hydrophilic Surfaces

Cited by 3 publications

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Can Wicking Control Droplet Cooling?

Can Wicking Control Droplet Cooling?

Nanoscale and Macroscale Effects of Mineral Deposition During Water Evaporation on Nanoporous Surfaces

Heat transport for evaporating droplets on superhydrophilic, thin, nanoporous layers

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