What question did this study set out to answer?

The research aims to explore how temperature affects the motion of ice blocks on surfaces with asymmetry.

February 11, 2026

Temperature-mediated directional self-propulsion of ice blocks on hot ratchet surfaces

Key Points

The research aims to explore how temperature affects the motion of ice blocks on surfaces with asymmetry.
Investigated ice block motion on superheated ratchet surfaces.
Examined phase change interactions between solid, liquid, and vapor.
Analyzed temperature effects on motion direction and stability.
Observed that ice blocks self-propel below and above 400 °C.
Identified bidirectional motion in the transition-boiling regime and unidirectional propulsion in the vapor-meltwater cushion.
Established new frameworks for understanding thermal transport in solid-liquid-vapor systems.

Abstract

The interplay between phase change and surface asymmetry enables remarkable self-propulsion. We report temperature-mediated motion of ice blocks on superheated ratchet surfaces, revealing a three-phase Leidenfrost regime bridging melting and vapor levitation. Below around 400 °C, asymmetric meltwater ejection within the transition-boiling regime drives geometry-dependent bidirectional motion. Above this threshold, a stable vapor-meltwater cushion forms, producing unidirectional propulsion via pressure rectification. The coupling of melting, boiling, and asymmetric confinement extends the Leidenfrost framework to solid–liquid–vapor systems, offering new insight into autonomous thermal transport and self-regulated cooling.

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Temperature-mediated directional self-propulsion of ice blocks on hot ratchet surfaces

Key Points

Abstract

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