Soft Condensation

Ambre Bouillant; Christopher Henkel; Uwe Thiele; Bruno Andreotti; Jacco H. Snoeijer

doi:10.1103/PhysRevLett.134.188204

Soft Condensation

Ambre Bouillant, Christopher Henkel, Uwe Thiele, Bruno Andreotti, Jacco H. Snoeijer

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Abstract

When moist air meets a cold surface, it creates a breath figure characterized by numerous small droplets. The central question is how the vapor flux is distributed between the growth of condensed drops and the nucleation of new ones. Here, we investigate the nucleation, growth, and coalescence of droplets on soft substrates consisting of cross-linked polymer networks. The number of droplets initially remains constant, until drops start to coarsen according to a universal law; both phenomena are explained via the formation of a saturated boundary layer. We quantitatively unveil an algebraic sensitivity of the number of droplets on substrate elasticity, which is unexpected since nucleation occurs at a scale where the polymer network resembles a melt. Breath figures thus offer a macroscopic probe of the molecular characteristics of the polymer surface, and suggest a surprisingly low-energy pathway for nucleation.

Original language	English
Article number	188204
Journal	Physical review letters
Volume	134
Issue number	18
DOIs	https://doi.org/10.1103/PhysRevLett.134.188204
Publication status	Published - 9 May 2025

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10.1103/PhysRevLett.134.188204

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abstract = "When moist air meets a cold surface, it creates a breath figure characterized by numerous small droplets. The central question is how the vapor flux is distributed between the growth of condensed drops and the nucleation of new ones. Here, we investigate the nucleation, growth, and coalescence of droplets on soft substrates consisting of cross-linked polymer networks. The number of droplets initially remains constant, until drops start to coarsen according to a universal law; both phenomena are explained via the formation of a saturated boundary layer. We quantitatively unveil an algebraic sensitivity of the number of droplets on substrate elasticity, which is unexpected since nucleation occurs at a scale where the polymer network resembles a melt. Breath figures thus offer a macroscopic probe of the molecular characteristics of the polymer surface, and suggest a surprisingly low-energy pathway for nucleation.",

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AB - When moist air meets a cold surface, it creates a breath figure characterized by numerous small droplets. The central question is how the vapor flux is distributed between the growth of condensed drops and the nucleation of new ones. Here, we investigate the nucleation, growth, and coalescence of droplets on soft substrates consisting of cross-linked polymer networks. The number of droplets initially remains constant, until drops start to coarsen according to a universal law; both phenomena are explained via the formation of a saturated boundary layer. We quantitatively unveil an algebraic sensitivity of the number of droplets on substrate elasticity, which is unexpected since nucleation occurs at a scale where the polymer network resembles a melt. Breath figures thus offer a macroscopic probe of the molecular characteristics of the polymer surface, and suggest a surprisingly low-energy pathway for nucleation.

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Soft Condensation

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