Pool Boiling Reliability Tests and Degradation Mechanisms of Microporous Copper Inverse Opal (CuIOs) Structures: Preprint

Kaiying Jiang, Daeyoung Kong, Kiwan Kim, Sreekant Narumanchi, James Palko, Ercan Dede, Chulmin Ahn, Hyoungsoon Lee, Mehdi Asheghi, Kenneth Goodson

Research output: Contribution to conferencePaper

Abstract

The rising power density in electronic systems requires thermal management solutions that are both high-performing and reliable. Porous materials such as Copper Inverse Opals (CuIOs) have unique structural features, including high permeability and high thermal conductivity, to enhance pool boiling performance. However, there is little understanding of the degradation mechanism of such porous materials under pool boiling conditions. In this study, samples of 10-micrometer-thick CuIOs with 4.8-micrometer diameter, covering silicon substrate of area 11-mm by 11-mm, with various heated areas ranging from 2.5-mm by 2.5-mm to 10-mm by 10-mm, were tested in 100 degrees C deionized water at a constant heat flux of 110 watts per square cm for 3-7 days. The combined effect of erosion and corrosion caused structural degradation of the CuIOs. The directly heated area had the most severe degradation while the edge of the heater and the unheated area showed progressively less degradation, maintaining some CuIOs structure even after the 7-day reliability test. Among all the tested samples with various heater sizes, the 2.5-mm by 2.5-mm heater sample - in which the heater size was designed to be comparable to the water bubble characteristic length - had the largest critical heat flux (CHF) up to 300 watts per square cm with a superheat of approximately 13 degrees C. Additionally, CuIOs with a smaller heated area performed better in terms of reliability. This study offers preliminary insights into CuIOs degradation mechanisms, contributing to the development of more robust thermal management solutions. We expect that electroless plating of CuIOs with gold (Au), nickel (Ni), and atomic layer deposition of aluminum oxide in combination with appropriate application-specific coolants will further improve the reliability and lifetime of the CuIOs.
Original languageAmerican English
Number of pages11
StatePublished - 2024
EventITherm 2024 - Denver, CO
Duration: 28 May 202431 May 2024

Conference

ConferenceITherm 2024
CityDenver, CO
Period28/05/2431/05/24

NREL Publication Number

  • NREL/CP-5400-88663

Keywords

  • boiling-induced degradation
  • copper inverse opal
  • corrosion
  • erosion
  • thermal degradation
  • water

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