2016
DOI: 10.1016/j.ijheatmasstransfer.2016.04.107
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Design of micropillar wicks for thin-film evaporation

Abstract: The generation of concentrated heat loads in advanced microprocessors, GaN electronics, and solar cells present significant thermal management challenges in defense, space and commercial applications. Liquid to vapor phase-change strategies are promising due to the high latent heat of vaporization of the working fluid. In particular, thin-film evaporation has received increased interest owing to advances in micro/nanofabrication and the potential to dissipate high heat fluxes by increasing the evaporative meni… Show more

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Cited by 128 publications
(84 citation statements)
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“…The heat fluxes dissipated using our nanoporous membranes are 13.5 × higher than the highest previously reported heat fluxes in a pure evaporation regime for any fluid, dielectric or conducting, when normalizing to the evaporation area 14,16 . Previous work has demonstrated heat fluxes of 160-5 800 W/cm 2 normalized to the heater area with an evaporator-to-heater area ratio of 18-250, respectively 14,29 .…”
Section: Discussionmentioning
confidence: 62%
See 1 more Smart Citation
“…The heat fluxes dissipated using our nanoporous membranes are 13.5 × higher than the highest previously reported heat fluxes in a pure evaporation regime for any fluid, dielectric or conducting, when normalizing to the evaporation area 14,16 . Previous work has demonstrated heat fluxes of 160-5 800 W/cm 2 normalized to the heater area with an evaporator-to-heater area ratio of 18-250, respectively 14,29 .…”
Section: Discussionmentioning
confidence: 62%
“…Since the capillary and viscous pressures are coupled to pore size, the highest critical heat flux (CHF) are typically for sintered wicks with particle sizes of 250-355 µm using water. This CHF is~500 W/cm 2 with nucleate boiling in the wicking structure and 50-80 W/cm 2 with pure evaporation [13][14][15][16] , that is, without nucleate boiling. Similarly, the overall heat transfer coefficient (h = q″/ΔT) in traditional capillary-driven evaporation structures is dominated by heat conduction in the wicking structure as well as through the evaporating liquid film.…”
Section: Introductionmentioning
confidence: 99%
“…A variety of heat sink designs have been employed to dissipate larger heat fluxes by delaying CHF or reducing the pressure drop in two-phase operation compared to a conventional design with straight, parallel channels fed by a single header. These designs have implemented one or more of features such as vapor venting [10], pin-fins and interrupted channels of various shapes and configurations [10][11][12], wick structures to aid in thin film evaporation [13][14][15], microchannels with reentrant cavities and/or inlet restrictors [16], microgaps [17], arrays of jets [18][19][20][21], diverging channels [22,23], microchannels fed with tapered manifolds [24], and stacked heat sinks [25]. Heat fluxes as high as 1127 W/cm² have been dissipated with dielectric fluids [26] using a 10 mm × 20 mm copper heat sink that incorporated both flow boiling in microchannels and jet impingement.…”
Section: Introductionmentioning
confidence: 99%
“…Vaporization of water is a common phenomenon that contributes significantly to the utilization and production of fresh water in living organisms and industry [11,12]. In industries, the steam is generated by two means.…”
Section: Introductionmentioning
confidence: 99%