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Autori principali: Kiseleva, Mariia S., Karki, Tytti, Latikka, Mika, Koochak, Parham, Lepikko, Sakari, Vuckovac, Maja, Koskinen, Tomi, Raju, Ramesh, Jokinen, Ville P., Liu, Jiazheng, Miljkovic, Nenad, Timonen, Jaakko V. I., Tittonen, Ilkka, Ras, Robin H. A.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2512.11861
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author Kiseleva, Mariia S.
Karki, Tytti
Latikka, Mika
Koochak, Parham
Lepikko, Sakari
Vuckovac, Maja
Koskinen, Tomi
Raju, Ramesh
Jokinen, Ville P.
Liu, Jiazheng
Miljkovic, Nenad
Timonen, Jaakko V. I.
Tittonen, Ilkka
Ras, Robin H. A.
author_facet Kiseleva, Mariia S.
Karki, Tytti
Latikka, Mika
Koochak, Parham
Lepikko, Sakari
Vuckovac, Maja
Koskinen, Tomi
Raju, Ramesh
Jokinen, Ville P.
Liu, Jiazheng
Miljkovic, Nenad
Timonen, Jaakko V. I.
Tittonen, Ilkka
Ras, Robin H. A.
contents Water condensation on superhydrophobic surfaces can generate spontaneous droplet jumping, enabling rapid condensate removal and improved thermal and mass transfer. Although this effect has been extensively demonstrated on densely packed nanostructures, the capability of microscale textures to support jumping condensation remains poorly understood. Here, we show that engineered microscale conical arrays can achieve efficient microdroplet jumping and reveal a previously unreported spacing-dependent critical transition between jumping and non-jumping regimes. In the jumping regime, by varying only the cone pitch, we identify a geometric threshold below which sub-10 micron droplets are rapidly removed, and above which jumping is suppressed, resulting in slower dynamics and larger departing droplets. In situ optical and environmental scanning electron microscopies reveal the mechanistic origin of this transition: dense arrays favour full Cassie droplets, which depart cleanly, while wider spacing favours partial Cassie droplets that retain a localized wet region initiating new nucleation. From these results, we construct a geometry-wetting design map linking microstructure spacing, droplet morphology, and nucleation density. These findings establish design principles for scalable, mechanically robust microstructured surfaces capable of high-performance condensation management for anti-fogging, water harvesting, and heat-transfer applications.
format Preprint
id arxiv_https___arxiv_org_abs_2512_11861
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Unlocking the full potential of jumping condensation on microstructured surfaces
Kiseleva, Mariia S.
Karki, Tytti
Latikka, Mika
Koochak, Parham
Lepikko, Sakari
Vuckovac, Maja
Koskinen, Tomi
Raju, Ramesh
Jokinen, Ville P.
Liu, Jiazheng
Miljkovic, Nenad
Timonen, Jaakko V. I.
Tittonen, Ilkka
Ras, Robin H. A.
Soft Condensed Matter
Fluid Dynamics
Water condensation on superhydrophobic surfaces can generate spontaneous droplet jumping, enabling rapid condensate removal and improved thermal and mass transfer. Although this effect has been extensively demonstrated on densely packed nanostructures, the capability of microscale textures to support jumping condensation remains poorly understood. Here, we show that engineered microscale conical arrays can achieve efficient microdroplet jumping and reveal a previously unreported spacing-dependent critical transition between jumping and non-jumping regimes. In the jumping regime, by varying only the cone pitch, we identify a geometric threshold below which sub-10 micron droplets are rapidly removed, and above which jumping is suppressed, resulting in slower dynamics and larger departing droplets. In situ optical and environmental scanning electron microscopies reveal the mechanistic origin of this transition: dense arrays favour full Cassie droplets, which depart cleanly, while wider spacing favours partial Cassie droplets that retain a localized wet region initiating new nucleation. From these results, we construct a geometry-wetting design map linking microstructure spacing, droplet morphology, and nucleation density. These findings establish design principles for scalable, mechanically robust microstructured surfaces capable of high-performance condensation management for anti-fogging, water harvesting, and heat-transfer applications.
title Unlocking the full potential of jumping condensation on microstructured surfaces
topic Soft Condensed Matter
Fluid Dynamics
url https://arxiv.org/abs/2512.11861