Thermal resistance of heated superhydrophobic channels with thermocapillary stress
Tomlinson, Samuel D. ORCID: https://orcid.org/0000-0002-7180-9443, Mayer, Michael D., Kirk, Toby L., Hodes, Marc and Papageorgiou, Demetrios T.
(2023)
Thermal resistance of heated superhydrophobic channels with thermocapillary stress.
ASME Journal of Heat and Mass Transfer, 146 (2):0216.
ISSN 2832-8450 (Print), 2832-8469 (Online)
(doi:10.1115/1.4063880)
![]() |
PDF (VoR)
51094 TOMLISON_Thermal_Resistance_Of_Heated_Superhydrophobic_Channels_With_Thermocapillary_Stress_(FREE ACCESS VoR)_2023.pdf - Published Version Restricted to Repository staff only Download (3MB) | Request a copy |
Abstract
A pressure-driven channel flow between a longitudinally ridged superhydrophobic surface (SHS) and solid wall is studied, where a constant heat flux enters the channel from either the SHS or solid wall. First, a model is developed which neglects thermocapillary stresses (TCS) in the transverse direction. The caloric, convective, and total thermal resistance are evaluated, and their dependence on the shape of the liquid–gas interface (meniscus), gas ridge width, texture period, channel height, streamwise TCS, Péclet number, and channel length is established. The caloric resistance is minimized with menisci that protrude into the gas cavity, large slip fractions, small channel heights, and small streamwise TCSs. When heating from the SHS, the convective resistance increases, and therefore, a design compromise exists between caloric and convective resistances. However, when heating from the solid wall, the convective resistance remains the same and SHSs that minimize caloric resistance are optimal. We investigate both water and Galinstan for microchannel applications and find that both configurations can have a lower total thermal resistance than a smooth-walled channel. Heating from the solid wall is shown to always have the lowest total thermal resistance. Numerical simulations are used to analyze the effect of transverse TCSs. Our model captures much of the physics in heated superhydrophobic channels but is computationally inexpensive when compared to the numerical simulations.
Item Type: | Article |
---|---|
Uncontrolled Keywords: | heating, stress, thermal resistance, water, cavities, temperature, computer simulation, flow (dynamics), heat |
Subjects: | Q Science > Q Science (General) Q Science > QA Mathematics Q Science > QA Mathematics > QA75 Electronic computers. Computer science |
Faculty / School / Research Centre / Research Group: | Faculty of Engineering & Science Faculty of Engineering & Science > School of Computing & Mathematical Sciences (CMS) |
Last Modified: | 26 Sep 2025 15:07 |
URI: | https://gala.gre.ac.uk/id/eprint/51094 |
Actions (login required)
![]() |
View Item |
Downloads
Downloads per month over past year