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Metal functionalization of carbon nanotubes for enhanced sintered powder wicks

By Arun S. Kousalya, Justin A. Weibel, Suresh V. Garimella and Timothy S. Fisher


Phase change cooling schemes involving passive heat spreading devices, such as heat pipes and vapor chambers, are widely adopted for thermal management of high heat-flux technologies. In this study, carbon nanotubes (CNTs) are fabricated on a 200 mu m thick sintered copper powder wick layer using microwave plasma enhanced chemical vapor deposition technique. A physical vapor deposition process is used to coat the CNTs with a varying thickness of copper to promote surface wetting with the working fluid, water. Thermal performance of the bare sintered copper powder sample (without CNTs) and the copper-functionalized CNT-coated sintered copper powder wick samples is compared using an experimental facility that simulates the capillary fluid feeding conditions of a vapor chamber. A notable reduction in the boiling incipience superheat is observed for the nanostructured samples. Additionally, nanostructured samples having a thicker copper coating provided a considerable increase in dryout heat flux, supporting heat fluxes up to 457 W/cm(2) from a 5 mm X 5 rum heat input area, while maintaining lower surface superheat temperatures compared to a bare sintered powder sample; this enhancement is attributed primarily to the improved surface wettability. Dynamic contact angle measurements are conducted to quantitatively compare the surface wetting trends for varying copper coating thicknesses and confirm the increase in hydrophilicity with increasing coating thickness. (C) 2012 Elsevier Ltd. All rights reserved

Topics: Vapor chamber; Heat pipe; Carbon nanotube (CNT); Dryout heat flux; Boiling; Surface functionalization; POOL BOILING PERFORMANCE; CRITICAL HEAT-FLUX; POROUS STRUCTURES; LIQUID DROPLETS; JET IMPINGEMENT; CONTACT-ANGLE; SURFACES; TEMPERATURE; DYNAMICS; IMPACT, Nanoscience and Nanotechnology
Publisher: 'Elsevier BV'
Year: 2013
DOI identifier: 10.1016/j.ijheatmasstransfer.2012.12.030
OAI identifier:
Provided by: Purdue E-Pubs
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