Enregistré dans:
Détails bibliographiques
Auteurs principaux: Huo, Shasha, Sun, Bo
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2502.18117
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866929756874735616
author Huo, Shasha
Sun, Bo
author_facet Huo, Shasha
Sun, Bo
contents While Moore's Law has approached its physical limits lately, the high integration and miniaturisation of electronics have also brought another thermal failure obstacle. Previous studies on single-phase flow demanded significant pump power to achieve higher CHF, but this approach risked exceeding the chip's mechanical limits and complicating packaging. The elevated junction temperature (above 175 C) of third-generation semiconductors makes them ideal for two-phase water cooling which utilizes the huge latent heat during boiling of water to minimize the flow rate and maximize the COP. In this work, we designed an embedded hierarchical microchannel heat sink for heat transfer by deionised water two-phase cooling. We observed an unprecedented Critical Heat Flux (CHF) of 1682W cm-2 with COP up to 23615 at flow rate of 3.0 ml s-1, which means Only 70 mW of power is needed to take away the heat on the 1682 W per square centimetre chip, corresponding to a 3-fold increase compared to single-phase microchannels with same flowrate. At a high flow rate of 10 ml s-1, we even achieved a remarkable heat flux of 2500 W cm-2. This technology is anticipated to overcome the bottleneck in electronic thermal management.
format Preprint
id arxiv_https___arxiv_org_abs_2502_18117
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Two-Phase Boiling in a Replaceable Embedded Heat Sink for Ultra-High Heat Flux SiC Chip Cooling
Huo, Shasha
Sun, Bo
Fluid Dynamics
While Moore's Law has approached its physical limits lately, the high integration and miniaturisation of electronics have also brought another thermal failure obstacle. Previous studies on single-phase flow demanded significant pump power to achieve higher CHF, but this approach risked exceeding the chip's mechanical limits and complicating packaging. The elevated junction temperature (above 175 C) of third-generation semiconductors makes them ideal for two-phase water cooling which utilizes the huge latent heat during boiling of water to minimize the flow rate and maximize the COP. In this work, we designed an embedded hierarchical microchannel heat sink for heat transfer by deionised water two-phase cooling. We observed an unprecedented Critical Heat Flux (CHF) of 1682W cm-2 with COP up to 23615 at flow rate of 3.0 ml s-1, which means Only 70 mW of power is needed to take away the heat on the 1682 W per square centimetre chip, corresponding to a 3-fold increase compared to single-phase microchannels with same flowrate. At a high flow rate of 10 ml s-1, we even achieved a remarkable heat flux of 2500 W cm-2. This technology is anticipated to overcome the bottleneck in electronic thermal management.
title Two-Phase Boiling in a Replaceable Embedded Heat Sink for Ultra-High Heat Flux SiC Chip Cooling
topic Fluid Dynamics
url https://arxiv.org/abs/2502.18117