Inhibiting the Leidenfrost effect above 1,000 °C for sustained thermal cooling

Research output: Journal Publications and ReviewsRGC 21 - Publication in refereed journalpeer-review

147 Scopus Citations
View graph of relations

Author(s)

  • Mengnan Jiang
  • Yang Wang
  • Hanheng Du
  • Suet To
  • Jihong Yu
  • David Quéré
  • Zuankai Wang

Detail(s)

Original languageEnglish
Pages (from-to)568-572
Journal / PublicationNature
Volume601
Issue number7894
Online published26 Jan 2022
Publication statusPublished - 27 Jan 2022

Abstract

The Leidenfrost effect, namely the levitation of drops on hot solids1, is known to deteriorate heat transfer at high temperature2. The Leidenfrost point can be elevated by texturing materials to favour the solid–liquid contact2–10 and by arranging channels at the surface to decouple the wetting phenomena from the vapour dynamics3. However, maximizing both the Leidenfrost point and thermal cooling across a wide range of temperatures can be mutually exclusive3,7,8. Here we report a rational design of structured thermal armours that inhibit the Leidenfrost effect up to 1,150 °C, that is, 600 °C more than previously attained, yet preserving heat transfer. Our design consists of steel pillars serving as thermal bridges, an embedded insulating membrane that wicks and spreads the liquid and U-shaped channels for vapour evacuation. The coexistence of materials with contrasting thermal and geometrical properties cooperatively transforms normally uniform temperatures into non-uniform ones, generates lateral wicking at all temperatures and enhances thermal cooling. Structured thermal armours are limited only by their melting point, rather than by a failure in the design. The material can be made flexible, and thus attached to substrates otherwise challenging to structure. Our strategy holds the potential to enable the implementation of efficient water cooling at ultra-high solid temperatures, which is, to date, an uncharted property.

Citation Format(s)

Inhibiting the Leidenfrost effect above 1,000 °C for sustained thermal cooling. / Jiang, Mengnan; Wang, Yang; Liu, Fayu et al.
In: Nature, Vol. 601, No. 7894, 27.01.2022, p. 568-572.

Research output: Journal Publications and ReviewsRGC 21 - Publication in refereed journalpeer-review