Lifshitz interaction can promote ice growth at water-silica interfaces

Boström, Mathias; Malyi, Oleksandr I.; Parashar, Prachi; Shajesh, K. V.; Thiyam, Priyadarshini; Milton, Kimball A.; Persson, Clas; Parsons, Drew F.; Brevik, Iver

doi:10.1103/physrevb.95.155422

Cited by 13 publications

(52 citation statements)

References 55 publications

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“…In contrast to their results, we have found that buoyancy combined with dispersion and double layer forces establish an equilibrium where large ice particles float on the surface while small (micron-sized) ice particles are trapped at a distance below a water surface [45]. Further, it was shown that ice formation can be induced by dispersion forces near silica-water interfaces (where silica can be used as a model for rock material) [34]. For CO 2 gas hydrates and the N 2 gas hydrate, energy minimum exist corresponding in each case to an equilibrium ice film thickness: d CO2 =44, 43 and 37 Å for CO 2 volume fractions p = 5.75, 6 and 7.67, respectively, and d N2 =32 Å.…”

Section: Gas Hydrate Specific Ice Formationcontrasting

confidence: 82%

“…These dielectric functions are for a system at the triple point of water, close to zero degrees Celsius at low pressure. The final results for ice melting [19,20,21,22,23,31,32] and water freezing [33,34] are sensitive to the dielectric functions of ice and water since these are extremely similar when the water is in equilibrium with the ice. We show in Fig.…”

Section: Materials Modellingmentioning

confidence: 99%

“…In the remainder of this letter, we use ice JD , the Daniels [29] model for ice, since both models give very similar results. The thicknesses correlate with the frequency where the dielectric functions of ice and water have a crossing [34]. Figure 5 shows the free energy as a function of ice film thickness for different gas hydrates in ice cold water.…”

Section: Gas Hydrate Specific Ice Formationmentioning

confidence: 99%

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Dispersion Forces Stabilize Ice Coatings at Certain Gas Hydrate Interfaces That Prevent Water Wetting

Boström

Corkery

Lima

et al. 2019

ACS Earth Space Chem.

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Gas hydrates formed in oceans and permafrost occur in vast quantities on Earth representing both a massive potential fuel source and a large threat in climate forecasts. They have been predicted to be important on other bodies in our solar systems such as Enceladus, a moon of Saturn. CO 2 -hydrates likely drive the massive gas-rich water plumes seen and sampled by the spacecraft Cassini, and the source of these hydrates is thought to be due to buoyant gas hydrate particles. Dispersion forces cause gas hydrates to be coated in a 3-4 nm thick film of ice, or to contact water directly, depending on which gas they contain. These films are shown to significantly alter the properties of the gas hydrate clusters, for example, whether they float or sink. It is also expected to influence gas hydrate growth and gas leakage.

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Section: Gas Hydrate Specific Ice Formationcontrasting

confidence: 82%

Section: Materials Modellingmentioning

confidence: 99%

Section: Gas Hydrate Specific Ice Formationmentioning

confidence: 99%

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Dispersion Forces Stabilize Ice Coatings at Certain Gas Hydrate Interfaces That Prevent Water Wetting

Boström

Corkery

Lima

et al. 2019

ACS Earth Space Chem.

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“…As an application of the results found here, that ice grows inside water at the triple point of water, we would like to investigate the relevance of this effect to the predictions for liquid water on distant planets and their moons. In presence of a silica surface we have predicted that ice can form in water based on Lifshitz theory [17]. Boström et al further proposed that Lifshitz forces could lead to ice formation on some specific gas hydrate surfaces in water [39].…”

Section: Discussionmentioning

confidence: 99%

“…This expression leads to d 1 ≈ 0.41 µm and d 2 ≈ 7.83nm, which are in the right ballpark of 0.37 µm and 3.56nm, respectively. We have been unable to find a more accurate analytical estimate, because we are dealing with a discrete function of the Matsubara mode numbers n, in addition to the fact that the zero mode behaves significantly differently from other modes [17].…”

Section: Lifshitz Energy For Planar Geometrymentioning

confidence: 99%

Role of zero point energy in promoting ice formation in a spherical drop of water

Parashar

Shajesh

Milton

et al. 2019

Phys. Rev. Research

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We demonstrate that the Lifshitz interaction energy (excluding the self-energies of the inner and outer spherical regions) for three concentric spherical dielectric media can be evaluated easily using the immense computation power in recent processors relative to those of a few decades ago. As a prototype, we compute the Lifshitz interaction energy for a spherical shell of water immersed in water vapor of infinite extent while enclosing a spherical ball of ice inside the shell, such that two concentric spherical interfaces are formed: one between solid ice and liquid water and the other between liquid water and gaseous vapor. We evaluate the Lifshitz interaction energy for the above configuration at the triple point of water when the solid, liquid, and gaseous states of water coexist, and, thus, extend the analysis of Elbaum and Schick in Phys. Rev. Lett. 66 (1991) 1713 to spherical configurations. We find that, when the Lifshitz energy contributes dominantly to the total energy of this system, which is often the case when electrostatic interactions are absent, a drop of water surrounded by vapor of infinite extent is not stable at the triple point. This instability, that is a manifestation of the quantum fluctuations in the medium, will induce nucleation of ice in water, which will then grow in size indefinitely. This is a consequence of the finding here that the Lifshitz energy is minimized for large (micrometer size) radius of the ice ball and small (nanometer size) thickness of the water shell surrounding the ice. These results might be relevant to the formation of hail in thunderclouds. These results are tentative in that the self-energies are omitted. * Prachi.Parashar@jalc.edu † with inter-atomic forces. However, the astonishing feat of Casimir [10] was in showing that London dispersion forces, or the van der Waals interactions, were manifestations of the zero point energy.Casimir evaluated the energy of a planar cavity with perfectly conducting walls, an overly idealized system, that is obtained from the configuration of Fig. 1 when the regions labeled as ε 1 and ε 2 are perfect electrical conductors that are separated by vacuum in the background region labeled ε 3 . Lifshitz [11] generalized Casimir's result by evaluating the energy for a configuration of Fig. 1 consisting of two dielectric media of infinite extent separated by vacuum. The Lifshitz energy leads to the Casimir energy in the perfect conducting limit of the dielectric functions for the outer media. Dzyaloshinskii, Lifshitz, and Pitaevskii (DLP) [12] extended these considerations for the case when the background region in the planar configuration of Fig. 1 is another uniform dielectric medium. The main idea underlying these groundbreaking works is that quantum fluctuations of fields in the media can be manifested in physical phenomena involving dielectrics. Among these, we point out that the configurations considered by Casimir and Lifshitz always lead to an attractive pressure (tending to decrease the thickness of the intervening medium). I...

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Surface Structure and Temperature‐Reversible Phase Transition of Sn on W(110) Surface

Banik

Nakagawa

2023

Physica Status Solidi (b)

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The growth of Sn overlayers on the W(110) surface is investigated using low‐energy electron diffraction analysis. The structural investigation reveals Sn adsorption sites on the W(110) for (1 × 3) and (1 × 4) structures. During the formation of the (1 × 3) structure, Sn atoms are only adsorbed on the threefold hollow sites. However, at higher coverages, Sn atoms are adsorbed on the fourfold hollow sites after the threefold hollow sites are filled up to form the (1 × 4) structure, resulting in a dense overlayer structure. Both structures are overlayer with no alloy formation at the interface. The (1 × 3) phase exhibits a temperature‐reversible phase transition below ≈270 K. At low temperatures, a phase with long‐range order is developed.

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Lifshitz interaction can promote ice growth at water-silica interfaces

Cited by 13 publications

References 55 publications

Dispersion Forces Stabilize Ice Coatings at Certain Gas Hydrate Interfaces That Prevent Water Wetting

Dispersion Forces Stabilize Ice Coatings at Certain Gas Hydrate Interfaces That Prevent Water Wetting

Role of zero point energy in promoting ice formation in a spherical drop of water

Surface Structure and Temperature‐Reversible Phase Transition of Sn on W(110) Surface

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