Close to the triple point, the surface of ice is covered by a thin liquid layer (so-called quasi-liquid layer) which crucially impacts growth and melting rates. Experimental probes cannot observe the growth processes below this layer, and classical models of growth by vapor deposition do not account for the formation of premelting films. Here, we develop a mesoscopic model of liquid-film mediated ice growth, and identify the various resulting growth regimes. At low saturation, freezing proceeds by terrace spreading, but the motion of the buried solid is conveyed through the liquid to the outer liquid–vapor interface. At higher saturations water droplets condense, a large crater forms below, and freezing proceeds undetectably beneath the dro...
In this paper we study the structure of the ice/vapor interface in the neighborhood of the triple po...
With climate modeling predicting a raise of at least 2°C by year 2100, the fate of ice has become a ...
We analyse the growth rate of segregated ice (ice lenses) in freezing porous media. For typical coll...
Close to the triple point, the surface of ice is covered by a thin liquid layer (so-called quasi-liq...
We examine ice crystallization from liquid water and from water vapor, focusing on the underlying ph...
We examine ice crystal growth from water vapor at temperatures near the melting point, when surface ...
We perform computer simulations of the quasi-liquid layer of ice formed at the ice/vapor interface c...
Surfaces of ice are covered with thin liquid water layers, called quasi-liquid layers (QLLs), even b...
ConspectusThe ice premelt, often called the quasi-liquid layer (QLL), is key for the lubrication of ...
A vast amount of ice exists on the earth, and surface melting of ice forms thin liquid water layers,...
Abstract. We examine the molecular dynamics of crystal growth in the presence of surface melting and...
Surface melting of ice crystals proceeds below the melting point (0 °C) and forms thin liquid water ...
Ice crystal surfaces melt at temperatures below 0 °C, and then quasi-liquid layers (QLLs) are formed...
With climate modeling predicting a raise of at least 2°C by year 2100, the fate of ice has become a ...
Frozen water has a quasi-liquid layer at its surface that exists even well below the bulk melting te...
In this paper we study the structure of the ice/vapor interface in the neighborhood of the triple po...
With climate modeling predicting a raise of at least 2°C by year 2100, the fate of ice has become a ...
We analyse the growth rate of segregated ice (ice lenses) in freezing porous media. For typical coll...
Close to the triple point, the surface of ice is covered by a thin liquid layer (so-called quasi-liq...
We examine ice crystallization from liquid water and from water vapor, focusing on the underlying ph...
We examine ice crystal growth from water vapor at temperatures near the melting point, when surface ...
We perform computer simulations of the quasi-liquid layer of ice formed at the ice/vapor interface c...
Surfaces of ice are covered with thin liquid water layers, called quasi-liquid layers (QLLs), even b...
ConspectusThe ice premelt, often called the quasi-liquid layer (QLL), is key for the lubrication of ...
A vast amount of ice exists on the earth, and surface melting of ice forms thin liquid water layers,...
Abstract. We examine the molecular dynamics of crystal growth in the presence of surface melting and...
Surface melting of ice crystals proceeds below the melting point (0 °C) and forms thin liquid water ...
Ice crystal surfaces melt at temperatures below 0 °C, and then quasi-liquid layers (QLLs) are formed...
With climate modeling predicting a raise of at least 2°C by year 2100, the fate of ice has become a ...
Frozen water has a quasi-liquid layer at its surface that exists even well below the bulk melting te...
In this paper we study the structure of the ice/vapor interface in the neighborhood of the triple po...
With climate modeling predicting a raise of at least 2°C by year 2100, the fate of ice has become a ...
We analyse the growth rate of segregated ice (ice lenses) in freezing porous media. For typical coll...
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