Tuning Superhydrophilic Nanostructured Surfaces to Maximize Water Droplet Evaporation Heat Transfer Performance

Wemp, Claire K.; Carey, Van P.

doi:10.1115/1.4040142

Cited by 8 publications

(6 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A high-speed camera is mounted overhead the arrangement to visualize wicking from the top, while a side camera at an inclination of 12 o is used to monitor the temporal variation of the amount of liquid sitting on the top. As the nanochannels are mostly closed (buried) with openings only at micropores, water wicks to much larger distances compared to open structures ,,,, as we have reduced evaporation compared to capillary flow; this allows us to visualize and detect the wicking front with ease. The two cameras are synchronized based on the instant when the droplet touches the surface, and the maximum error in synchronization is estimated to be 0.053 s based on the frame rates.…”

Section: Methodsmentioning

confidence: 99%

“…Thin-film evaporation manifests itself in nearly all evaporation processes, − and surfaces are designed to amplify its occurrence to achieve high heat flux removal. ,, For example, over the past few years, micro/nanostructures have been fabricated on surfaces to passively wick the liquid and augment thin-film meniscus area, thus enhancing heat transfer. ,,,− The way in which liquid is supplied to such structured surfaces gives rise to two distinct scenarios, first where the surface is partially submerged in a pool of bulk liquid thus providing unlimited supply of liquid to the structures , and second where liquid supply to the structured surface is limited but recurs at regular intervals. An example of the latter is spray cooling ,, where micro/macrosized droplets are dispersed, at a desired frequency, onto a heated surface where the droplets wick into the structures creating thin-film regions.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Droplet Evaporation on Porous Nanochannels for High Heat Flux Dissipation

Poudel

Zou

Maroo

2020

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

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 distance, capillary pressure, viscous resistance and propagation coefficient are obtained at the high surface temperatures. Evaporation flux from the nanochannels/micropores is estimated from the droplet experiments, but is also independent confirmed via a new set of experiments where water is continuously fed to the sample through a microtube such that it matches the evaporation rate. High heat flux as high as ~294 W/cm 2 is achieved from channels and pores. The experimental findings are applied to evaluate the use of porous nanochannels geometry in spray cooling application, and is found to be capable of dissipating high heat fluxes upto ~77 W/cm 2 at temperatures below nucleation, thus highlighting the thermal management potential of fabricated geometry.

show abstract

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Droplet Evaporation on Porous Nanochannels for High Heat Flux Dissipation

Poudel

Zou

Maroo

2020

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

show abstract

“…For a nanostructured surface, capillarity is a dominant factor [147], and these dimensionless numbers are all much less than 1, meaning that the gravitational, kinetic and bulk surface energies can be neglected compared to the surface energy of the structured layer. The strong capillary pressure in the structured layer provides the driving force for liquid advancement against viscous resistance, creating a socalled hemispreading or capillary wicking region beyond the upper droplet contact line [87,129,138,[147][148][149], as shown in Fig. 14(f).…”

Section: Flow Confinementmentioning

confidence: 99%

Spray Cooling on Enhanced Surfaces: A Review of the Progress and Mechanisms

Wang

Jiang

2021

Journal of Electronic Packaging

View full text Add to dashboard Cite

The rapid development of electronics, energy and propulsion systems has led us to the point where their performances are limited by cooling capacities. Heat fluxes of 10~100, even over 1,000 W/cm2 need to be dissipated with minimum coolant flow rate in next-generation power electronics. Spray cooling is a high heat flux, uniform and efficient cooling technique proven effective in various applications. However, its cooling capacity and efficiency need to be further improved to meet next-generation ultrahigh-power applications. Engineering of surface properties and structures can fundamentally affect the liquid-wall interactions, thus becoming the most promising way to enhance spray cooling. However, the unclear mechanisms of surface-enhanced spray cooling cause lack of guiding principles for surface design. Here, progress in spray cooling on surfaces with structures of different scales are reviewed and their performances evaluated and compared. Spray cooling can achieve critical heat flux (CHF) above 945 W/cm2 and heat transfer coefficient (HTC) up to 57 W/cm2K on structured surfaces for pressurized nozzle and CHF and HTC up to 1250 W/cm2 and 250 W/cm2K, respectively, on a smooth surface with the assistance of secondary gas flow. CHF enhancement of 110% was achieved on hybrid micro- and nanostructured surfaces. A clear map of enhancement mechanisms is proposed after analysis. Some future concerns are also proposed. This work helps the understanding and design of engineered surfaces in spray cooling and provides insights for interdisciplinary applications of heat transfer and advanced engineering materials.

show abstract

“…Droplet evaporation is essential in many applications, including lab-on-a-chip technologies, inkjet printing, − biosensing, manufacturing, and cooling. − Evaporation is strongly coupled to the wettability of a surface, as observed in several studies. For example, biphilic patterns consisting of hydrophilic and hydrophobic spots are known to affect droplet evaporation , and the boiling characteristics of water .…”

Section: Introductionmentioning

confidence: 99%

A Dynamically Responsive Surface with Switchable Wettability for Efficient Evaporation and Self-Cleaning Abilities

Parisi

López

Narayanan

2022

ACS Appl. Eng. Mater.

View full text Add to dashboard Cite

Evaporation is crucial in many applications. One of the critical parameters affecting evaporation is surface wettability, which is often tailored using coatings and micro- or nanoscale features on the surface. While this approach has advanced many technologies, the ability to control wettability dynamically can add new functionalities and capabilities that were not possible before. This study demonstrates how a self-cleaning superhydrophobic surface with an equilibrium contact angle of 155° can dynamically change to a superhydrophilic surface with a contact angle near 0°, resulting in drastically different evaporation characteristics. Specifically, we find that the evaporation rate and surface temperature reduction due to the resulting cooling are 3 times higher due to the change in surface wettability. This change in wetting behavior is due to the use of an amino-silane [N-(2-aminoethyl)-11-aminoundecyltrimethoxysilane]-functionalized surface, which is altered in the presence of dilute acetic acid. Upon complete evaporation, the surface reverts to superhydrophobic behavior. This reversible behavior is not seen in traditional nonwetting coatings like perfluorodecyltrichlorosilane and lauric acid. This strategy for dynamic control of wettability and evaporation can lead to advancements in many applications ranging from self-assembly-based fabrication processes to oil–water separation and advanced thermal management technologies.

show abstract

Tuning Superhydrophilic Nanostructured Surfaces to Maximize Water Droplet Evaporation Heat Transfer Performance

Cited by 8 publications

References 31 publications

Droplet Evaporation on Porous Nanochannels for High Heat Flux Dissipation

Droplet Evaporation on Porous Nanochannels for High Heat Flux Dissipation

Spray Cooling on Enhanced Surfaces: A Review of the Progress and Mechanisms

A Dynamically Responsive Surface with Switchable Wettability for Efficient Evaporation and Self-Cleaning Abilities

Contact Info

Product

Resources

About