Phase‐Change Heat Transfer: Supercapillary Architecture‐Activated Two‐Phase Boundary Layer Structures for Highly Stable and Efficient Flow Boiling Heat Transfer (Adv. Mater. 2/2020) | Zendy

Li Wenming | Zendy; Wang Zuankai | Zendy; Yang Fanghao | Zendy; Alam Tamanna | Zendy; Jiang Mengnan | Zendy; Qu Xiaopeng | Zendy; Kong Fengyu | Zendy; Khan Ahmed Shehab | Zendy; Liu Minjie | Zendy; Alwazzan Mohammad | Zendy; Tong Yan | Zendy; Li Chen | Zendy

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Phase‐Change Heat Transfer: Supercapillary Architecture‐Activated Two‐Phase Boundary Layer Structures for Highly Stable and Efficient Flow Boiling Heat Transfer (Adv. Mater. 2/2020)

Author(s) -

Li Wenming,

Wang Zuankai,

Yang Fanghao,

Alam Tamanna,

Jiang Mengnan,

Qu Xiaopeng,

Kong Fengyu,

Khan Ahmed Shehab,

Liu Minjie,

Alwazzan Mohammad,

Tong Yan,

Li Chen

Publication year - 2020

Publication title -

advanced materials

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 10.707

H-Index - 527

eISSN - 1521-4095

pISSN - 0935-9648

DOI - 10.1002/adma.202070013

Subject(s) - materials science , heat transfer , boundary layer , boiling , thermodynamics , flow (mathematics) , critical heat flux , phase (matter) , mechanics , heat transfer coefficient , organic chemistry , physics , chemistry

The physical limit of flow boiling heat transfer is reported by Zuankai Wang, Chen Li, and co‐workers in article number 1905117. Textured supercapillary structures are designed in a microfluidic device to fundamentally transform the conventional chaotic phase‐transition process into a desirable two‐phase boundary layer structure. Exceptional thermal performances are achieved.

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