Universality of Tip Singularity Formation in Freezing Water Drops

Marin, Alvaro; Enríquez, Óscar R.; Brunet, Philippe; Colinet, Pierre; Snoeijer, Jacco H.

doi:10.1103/physrevlett.113.054301

Cited by 207 publications

(182 citation statements)

References 14 publications

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“…This calculation is based on the approximation that the propagation of this front can be split into two stages: a) the front is planar until it reaches a critical height when the shape of the droplet evolves into a cone due to the expansion of the volume of water when it freezes into ice, and b) afterwards, the front takes the shape of a spherical . cap centered at the apex of this cone 7,9 , illustrated in Fig. 3.…”

Section: Analytic Approximation For the Propagation Of The Ice-watmentioning

confidence: 99%

“…3). The angle θ is obtained by the requirement that upon freezing, the remaining volume of water expands into this cone and into the spherical cap 7,9 . The ratio ν = .917 of ice to water density determines θ ≈ 65 o , and corresponds to z 0 ≈ .64.…”

Section: Analytic Approximation For the Propagation Of The Ice-watmentioning

confidence: 99%

“…Recently, there has been some renewed interest in the properties of water droplets that are frozen on a planar surface at subzero temperatures [1][2][3][4]6,7,9 . A theoretical analysis, and numerical solutions of the heat diffusion differential equations for the propagation of the ice-water front in spherical droplets have been carried out by W.W. Schultz, M. G. Worster, and D.M.…”

Section: Introductionmentioning

confidence: 99%

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Theory and experiments on the ice–water front propagation in droplets freezing on a subzero surface

Nauenberg

2016

Eur. J. Phys.

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An approximate theory is presented describing the propagation of the ice-water front that develops in droplets of water that are deposited on a planar surface at a temperature below the melting point of ice. A calculation based on this theory is compared with our experimental observations of the time evolution of this front. The results of calculations of this front by Schultz et al 7 , obtained by integrating numerically the exact differential equations for this problem, were published graphically, but only for the time-dependent velocity of this front. Unfortunately, these theoretical results cannot be compared directly with our experimental observations. Our experiments were performed by freezing water droplets directly on a block of dry ice, and in order to examine the effects of the heat conductivity of a substrate during the freezing process, such droplets were also deposited on a glass plate and on a copper plate placed on dry ice. The temperature at the base of these droplets, and the dependence of the freezing time on their size was also investigated experimentally, and compared with our analytic approximation of the theory. Such experiment have not been published previously, and reveal that the usual assumption that the temperature at the base of the droplets is a constant, made in all previous theoretical papers on this subject, cannot be implemented in practice.

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Section: Analytic Approximation For the Propagation Of The Ice-watmentioning

confidence: 99%

Section: Analytic Approximation For the Propagation Of The Ice-watmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Theory and experiments on the ice–water front propagation in droplets freezing on a subzero surface

Nauenberg

2016

Eur. J. Phys.

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“…From daily experience we know that water freezing up inside a closed container can exert extreme pressures on its container walls, as is exemplified by the fracturing of rocks by freezing water inclusions [3] and by the playful "ice bomb", in which freezing water bursts out of a thickwalled metal flask [4]. For unenclosed water drops, it has been found that the combination of expansion and geometrical confinement by surface tension leads to the formation of a singular tip in the final stage of solidification [5]. However, in these experiments the spherical symmetry was purposefully broken by cooling the droplets only from one side.…”

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confidence: 99%

Fast Dynamics of Water Droplets Freezing from the Outside In

et al. 2017

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A drop of water that freezes from the outside-in presents an intriguing problem: the expansion of water upon freezing is incompatible with the self-confinement by a rigid ice shell. Using high-speed imaging we show that this conundrum is resolved through an intermittent fracturing of the brittle ice shell and cavitation in the enclosed liquid, culminating in an explosion of the partially frozen droplet. We propose a basic model to elucidate the interplay between a steady build-up of stresses and their fast release. The model reveals that for millimetric droplets the fragment velocities upon explosion are independent of the droplet size and only depend on material properties (such as the tensile stress of the ice and the bulk modulus of water). For small (sub-millimetric) droplets, on the other hand, surface tension starts to play a role. In this regime we predict that water droplets with radii below 50 µm are unlikely to explode at all. We expect our findings to be relevant in the modeling of freezing cloud and rain droplets.

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“…To minimize image distortion due to this meniscus, the glass is treated such that the wetting contact angle ≈ 90 • . This gives a clear view on the quasi-two-dimensional freezing process -typical videos can be found in the supplementary materials of [104]. Figure 6.3a shows that the solidification front in the Hele-Shaw cell grows towards the top of the drop in a similar fashion as the unconfined experiment, although the timescale of the process is a bit faster.…”

Section: Freezing Frontmentioning

confidence: 91%

Growing bubbles and freezing drops: depletion effects and tip singularities

Puente¹

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Universality of Tip Singularity Formation in Freezing Water Drops

Cited by 207 publications

References 14 publications

Theory and experiments on the ice–water front propagation in droplets freezing on a subzero surface

Theory and experiments on the ice–water front propagation in droplets freezing on a subzero surface

Fast Dynamics of Water Droplets Freezing from the Outside In

Growing bubbles and freezing drops: depletion effects and tip singularities

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