Condensation Induced Delamination of Nanoscale Hydrophobic Films

Ma, Jingcheng; Cha, Hyeongyun; Kim, Moon‐Kyung; Cahill, David G.; Miljkovic, Nenad

doi:10.1002/adfm.201905222

Cited by 70 publications

(66 citation statements)

References 34 publications

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“…Future work utilizing laser interference coupled with the endoscopy method presents a promising technique to further analyze the microlayer thickness with the aid of interference measurements. [ 5,60–62 ]…”

Section: Resultsmentioning

confidence: 99%

Endoscopic Visualization of Contact Line Dynamics during Pool Boiling on Capillary‐Activated Copper Microchannels

Zhu²,

Kang

et al. 2020

Adv Funct Materials

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Microchannel surfaces are common to microfluidics, biofluidics, thermal management, and energy applications. Due to processing limitations for the majority of metallic materials, the majority of hyperfine microchannels used in microfluidics and thermo‐fluids are fabricated on non‐metallic substrates, for example, silicon and polydimethylsiloxane. Here, a technique to fabricate ultrasmall microchannels on arbitrary metallic materials is developed using photolithography in combination with electrochemical deposition. The technique is used to prepare copper microchannels and to investigate the pool boiling heat transfer performance with a focus on the three‐phase contact line dynamics. The hydrodynamics of nucleating bubbles during boiling are observed in situ using in‐liquid endoscopy. The results show that the variation of critical heat flux enhancement has a linear relationship with the contact line increase ratio. The scalable microchannel surfaces exhibit superior heat transfer performance with a maximum heat transfer coefficient) enhancement of 930% with ultra‐low wall superheat of 5 °C. This work not only develops a scalable manufacturing method to develop ultra‐small microchannels on metallic materials, it outlines design guidelines for structure optimization of pool boiling heat transfer for temperature sensitive applications, such as electronics thermal management.

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Section: Resultsmentioning

confidence: 99%

Endoscopic Visualization of Contact Line Dynamics during Pool Boiling on Capillary‐Activated Copper Microchannels

Zhu²,

Kang

et al. 2020

Adv Funct Materials

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“…[33] Poor robustness of functionalized surfaces usually results from degradation of the hydrophobic coatings and poor mechanical integrity of the surface structures. [34,35] One potential avenue to extend the durability of the surfaces is to enable self-healing mechanisms, i.e., spontaneous regeneration or supply of the hydrophobic components after damage has occurred. [36][37][38][39] One approach to self-healing is to preserve excess fluoroalkylsilane moieties as healing agents in the micro/nanostructured porous matrix on the surface.…”

Section: Introductionmentioning

confidence: 99%

Atmosphere‐Mediated Scalable and Durable Biphilicity on Rationally Designed Structured Surfaces

Yan

Chen

Zhang

et al. 2020

Adv Materials Inter

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Biphilic surfaces having spatially distinct wetting have the potential to enable a plethora of applications ranging from fog harvesting, microfluidics, advanced manufacturing, and pumpless fluid transfer. However, complex and costly fabrication along with poor durability have hindered the widespread utilization of biphilic surfaces. Here we demonstrate hierarchical biphilic micro/nanostructured surfaces passively functionalized by the atmosphere as a platform to create scalable and abrasionresistant biphilic interfaces. We fabricate biphilic hierarchical copper oxide (CuO) nanowires on copper substrates via laser ablation followed by thermal oxidation. The surfaces spontaneously become globally superhydrophobic and locally hydrophilic due to the adsorption of airborne volatile organic compounds on the ultra-high surface energy CuO nanowires. The curvature-dependent spatial variation in nanowire morphology enables local roughness variation and wetting contrast without the need for selective functionalization. Coalescence-induced droplet jumping and water vapor

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“…Dropwise condensation occurs on non-wetting surfaces or partially wetting surfaces (Nouri et al 2012). After nine decades of research on dropwise condensation (Cho et al 2017;Emonsi 1939;Enright et al 2014;Miljkovic and Wang 2013;Schmidt et al 1930), design and fabrication of a surface that can sustain this mode of condensation for a long term have not been successful (Ahlers et al 2018;Ma et al 2019;Oh et al 2018). The main reason for this is that there is no united understanding of dropwise condensation phenomena because of the complexity of the physics involved.…”

Section: Introductionmentioning

confidence: 99%

Development of automated angle-scanning, high-speed surface plasmon resonance imaging and SPRi visualization for the study of dropwise condensation

et al. 2019

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This paper describes the fabrication and testing of a novel angle-scanning surface plasmon resonance imaging (SPRi) instrument. The combination of two stationary mirrors and two angle-controlled mirrors provides high accuracy (up to 10 −3°) and high-speed angular probing. This instrument minimizes the angle-dependent image artifact that arises due to beam walk, which is the biggest challenge for the use of SPRi with angular modulation (AM). In the work described in this paper, two linear stages were employed to minimize the image artifact by adjusting the location of the angle-controlled mirrors and the camera. The SPRi instrument was used to visualize coalescence during dropwise condensation. The results show that the effect of the environment's temperature on reflectance was less than 1% when the incident angle was carefully chosen for SPRi with intensity modulation (IM). This means that condensation visualization can be carried out at ambient temperatures, without the need for a Peltier stage or a thermally controlled condensing surface. The concept of pixel neighboring was employed to assess the probability of noise and the standard error of thin film measurement. Experimental analyses during dropwise condensation show (1) the presence of a thin film with thickness of one monolayer, and (2) surface coverage of 0.71 m 2 /m 2 by the thin film in the area between the droplets. In addition, analyses showed the existence of a dry area at the part of the substrate exposed by coalescence to ambient air. The results of this work undermine the validity of the film rupture theory as the dropwise condensation mechanism.

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Condensation Induced Delamination of Nanoscale Hydrophobic Films

Cited by 70 publications

References 34 publications

Endoscopic Visualization of Contact Line Dynamics during Pool Boiling on Capillary‐Activated Copper Microchannels

Endoscopic Visualization of Contact Line Dynamics during Pool Boiling on Capillary‐Activated Copper Microchannels

Atmosphere‐Mediated Scalable and Durable Biphilicity on Rationally Designed Structured Surfaces

Development of automated angle-scanning, high-speed surface plasmon resonance imaging and SPRi visualization for the study of dropwise condensation

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