Add to ORKG\u3cp\u3eWhen deposited on a hot bath, volatile drops are observed to stay in levitation: the so-called Leidenfrost effect. Here, we discuss drop dynamics in an inverse Leidenfrost situation where room-temperature drops are deposited on a liquid-nitrogen pool and levitate on a vapor film generated by evaporation of the bath. In the seconds following deposition, we observe that the droplets start to glide on the bath along a straight path, only disrupted by elastic bouncing close to the edges of the container. Initially at rest, these self-propelled drops accelerate within a few seconds and reach velocities on the order of a few centimeters per second before slowing down on a longer time scale. They remain self-propelled as long as they are ...
When a liquid droplet is placed on a very hot solid, it levitates on its own vapor layer, a phenomen...
It is well known that a liquid drop released over a very hot surface generally does not contact the ...
This work focuses on the Leidenfrost effect. A water drop placed on a hot substrate levitates on a c...
When deposited on a hot bath, volatile drops are observed to stay in levitation: the so-called Leide...
As discovered by Leidenfrost, liquids released over very hot solids levitate on a thin cushion of th...
We explore the interaction between a liquid drop (initially at room temperature) and a bath of liqui...
We theoretically investigate the behavior of Leidenfrost drops on a flat substrate submitted to a ho...
The Leidenfrost effect, classically associated with drops levitating on their own vapor over hot sol...
A liquid droplet dispensed over a sufficiently hot surface does not make contact but instead hovers ...
A liquid droplet dispensed over a sufficiently hot surface does not make contact but instead hovers ...
International audienceLiquids in the Leidenfrost state were shown by Linke to self-propel if placed ...
International audienceAs discovered by Leidenfrost, liquids placed on very hot solids levitate on a ...
In the Leidenfrost effect, a liquid drop stands above a very hot substrate and levitates over a bed ...
When a liquid droplet is placed on a very hot solid, it levitates on its own vapor layer, a phenomen...
It is well known that a liquid drop released over a very hot surface generally does not contact the ...
This work focuses on the Leidenfrost effect. A water drop placed on a hot substrate levitates on a c...
When deposited on a hot bath, volatile drops are observed to stay in levitation: the so-called Leide...
As discovered by Leidenfrost, liquids released over very hot solids levitate on a thin cushion of th...
We explore the interaction between a liquid drop (initially at room temperature) and a bath of liqui...
We theoretically investigate the behavior of Leidenfrost drops on a flat substrate submitted to a ho...
The Leidenfrost effect, classically associated with drops levitating on their own vapor over hot sol...
A liquid droplet dispensed over a sufficiently hot surface does not make contact but instead hovers ...
A liquid droplet dispensed over a sufficiently hot surface does not make contact but instead hovers ...
International audienceLiquids in the Leidenfrost state were shown by Linke to self-propel if placed ...
International audienceAs discovered by Leidenfrost, liquids placed on very hot solids levitate on a ...
In the Leidenfrost effect, a liquid drop stands above a very hot substrate and levitates over a bed ...
When a liquid droplet is placed on a very hot solid, it levitates on its own vapor layer, a phenomen...
It is well known that a liquid drop released over a very hot surface generally does not contact the ...
This work focuses on the Leidenfrost effect. A water drop placed on a hot substrate levitates on a c...