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Roman Giglio

University of California, Merced - Department of Mechanical Engineering

5200 Lake Rd,

Merced, CA 95343

United States

SCHOLARLY PAPERS

3

DOWNLOADS

221

TOTAL CITATIONS

1

Scholarly Papers (3)

Porous Mesh Manifold for Enhanced Pool Boiling Performance

Number of pages: 27 Posted: 14 Jun 2024
University of California, Merced - Department of Mechanical Engineering, University of California, Merced, Toyota Research Institue of North America, National Renewable Energy Laboratory, Stanford University, Stanford University and University of California, Merced - Department of Mechanical Engineering
Downloads 76 (840,816)
Citation 1

Abstract:

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Enhanced Pool Boiling, Critical Heat Flux, Electronics Cooling, Heat Transfer Coefficient

Porous Mesh Manifold for Enhanced Pool Boiling Performance

Number of pages: 27 Posted: 09 Jul 2024
University of California, Merced - Department of Mechanical Engineering, University of California, Merced, Toyota Research Institue of North America, National Renewable Energy Laboratory, Stanford University, Stanford University and University of California, Merced - Department of Mechanical Engineering
Downloads 40 (1,210,354)

Abstract:

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Phase change cooling, thermal management, Pool boiling, High heat flux

2.

Capillary-Driven Two-Phase Cooler for High-Heat-Flux Electronics Using Copper Wire Mesh Manifold and Enhanced Copper Inverse Opal Wick Heat Sink

Number of pages: 27 Posted: 28 May 2025
Stanford University, University of California, Merced - Department of Mechanical Engineering, Stanford University, University of California, Merced, Chung-Ang University, University of California, Merced - Department of Mechanical Engineering, Toyota Research Institue of North America, Stanford University and Stanford University
Downloads 84 (907,769)

Abstract:

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Capillary-driven boiling, copper wire mesh, copper inverse opal, two-phase heat transfer

3.

Exploring Capillary limits of Copper Wire Mesh Manifold for Area Scaling of Capillary-Driven Two-Phase Coolers

Number of pages: 30 Posted: 20 Apr 2026
Stanford University, University of California, Merced - Department of Mechanical Engineering, Stanford University, University of California, Merced, Chung-Ang University, University of California, Merced - Department of Mechanical Engineering, Toyota Research Institue of North America, Stanford University and Stanford University
Downloads 21 (1,500,778)

Abstract:

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Capillary-driven two-phase heat transfer, manifold, area-scaling, copper wire mesh, copper inverse opal