Drastic change of the Casimir force at the metal-insulator transition

Галкина, Е. Г.; Иванов, Б. А.; Savel’ev, Sergey; Yampol’skiı̆, V. A.; Nori, Franco

doi:10.1103/physrevb.80.125119

Cited by 22 publications

(20 citation statements)

References 49 publications

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“…[8,9,10,11,12,13,14]). The zero-temperature contribution to the force, originating from quantum fluctuations of the electromagnetic field, is well understood.…”

Section: Problems Linked To Lifshitz's Theory For the Casimir Forcementioning

confidence: 99%

Temperature dependence of the Casimir force for bulk lossy media

et al. 2010

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We discuss the limitations of the applicability of the Lifshitz formula to describe the temperature dependence of the Casimir force between two bulk lossy metals. These limitations follow from the finite sizes of the interacting bodies. Namely, Lifshitz's theory is not applicable when the characteristic wavelengths of the fluctuating fields, responsible for the temperature-dependent terms in the Casimir force, is longer than the sizes of the samples. As a result of this, the widely discussed linearly decreasing temperature dependence of the Casimir force can be observed only for dirty and/or large metal samples at high enough temperatures. This solves the problem of the inconsistency between the Nernst theorem and the "linearly decreasing temperature dependence" of the Casimir free energy, because this linear dependence is not valid when T → 0.

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“…[8,9,10,11,12,13,14]). The zero-temperature contribution to the force, originating from quantum fluctuations of the electromagnetic field, is well understood.…”

Section: Problems Linked To Lifshitz's Theory For the Casimir Forcementioning

confidence: 99%

Temperature dependence of the Casimir force for bulk lossy media

et al. 2010

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“…As it is well-known, the fluctuations theory [32] predicts Casimir forces between any pair of bodies, in contrast with our results, which give a vanishing force for two distinct dielectrics, for instance. The difference originates in the circumstance, usually overlooked, that the equivalent of our dispersion Equations (28) and (33) in the fluctuations theory have no solutions in some cases, as, for instance, for distinct dielectrics. The usual theorem of meromorphic functions, applied within the framework of the fluctuations theory [4][5][6], gives then a finite result, but it does not represent the energy of the eigenmodes.…”

Section: Discussionmentioning

confidence: 99%

“…If r 1,2 are the amplitudes of these fields (for a given polarization), then the dispersion Equations (28) and (33) are obtained from r 1 = r 2 e 2iκd . We note that |r 1,2 | 2 are the reflection coefficients, and for two perfectly reflecting bodies |r 1 | = |r 2 | = 1.…”

Section: Discussionmentioning

confidence: 99%

“…We can take the limit d → ∞ in Equation (33). It can be shown that this limit amounts formally to put e 2iκd = 0 [23].…”

Section: Surface Plasmon-polariton Modes Casimir Forcementioning

confidence: 99%

“…It was shown recently [33] that the van der Waals-London or Casimir forces may change drastically in complex materials, like poor conductors for instance, both in their numerical coefficients and in their d-dependence. Some of such changes seem to be related to the high-frequency dielectric functions ε (ω → ∞), which is not unity anymore, in contrast with our Equation (3).…”

Section: Surface Plasmons Van Der Waals-london Forcesmentioning

confidence: 99%

See 2 more Smart Citations

Electromagnetic Eigenmodes in Matter. Van Der Waals-London and Casimir Forces

Apostoł¹,

Vaman²

2010

PIER B

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Abstract-We derive van der Waals-London and Casimir forces by calculating the eigenmodes of the electromagnetic field interacting with two semi-infinite bodies (two halves of space) with parallel surfaces separated by distance d. We adopt simple models for metals and dielectrics, well-known in the elementary theory of dispersion. In the non-retarded (Coulomb) limit we get a d −3 -force (van der Waals-London force), arising from the zero-point energy (vacuum fluctuations) of the surface plasmon modes. When retardation is included we obtain a d −4 -(Casimir) force, arising from the zeropoint energy of the surface plasmon-polariton modes (evanescent modes) for metals, and from propagating (polaritonic) modes for identical dielectrics. The same Casimir force is also obtained for "fixed surfaces" boundary conditions, irrespective of the pair of bodies. The approach is based on the equation of motion of the polarization and the electromagnetic potentials, which lead to coupled integral equations. These equations are solved, and their relevant eigenfrequencies branches are identified.

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A Predictive Model for Monolayer‐Selective Metal‐Mediated MoS₂ Exfoliation Incorporating Electrostatics

Corletto,

Fronzi,

Joannidis

et al. 2023

Adv Materials Inter

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The metal‐mediated exfoliation (MME) method enables monolayer‐selective exfoliation of van der Waals (vdW) crystals, improving the efficacy of large monolayer production. Previous physical models explaining monolayer‐selective MME propose that the main contributors to monolayer‐selectivity are vdW crystal/metal surface binding energy and/or vdW crystal layer strain resulting from lattice mismatch. However, the performance of some metals for MME is inconsistent with these models. Here, a new model is proposed using MoS2 as a representative vdW crystal. The model explains how the MoS2/metal interface electrostatics, in combination with strain, determines monolayer‐selectivity of MME by modulating the MoS2 interlayer energy. Monolayer MoS2/metal interfaces are characterized using in situ Raman spectroscopy and density functional theory calculations to estimate the electrostatics and strain of MoS2 in contact with different metals. The model successfully demonstrates the dependence of MME monolayer‐selectivity on the MoS2/metal interface electrostatics and highlights the significance of electrostatics in nanomaterial vdW interactions.

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Drastic change of the Casimir force at the metal-insulator transition

Cited by 22 publications

References 49 publications

Temperature dependence of the Casimir force for bulk lossy media

Temperature dependence of the Casimir force for bulk lossy media

Electromagnetic Eigenmodes in Matter. Van Der Waals-London and Casimir Forces

A Predictive Model for Monolayer‐Selective Metal‐Mediated MoS₂ Exfoliation Incorporating Electrostatics

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Drastic change of the Casimir force at the metal-insulator transition

Cited by 22 publications

References 49 publications

Temperature dependence of the Casimir force for bulk lossy media

Temperature dependence of the Casimir force for bulk lossy media

Electromagnetic Eigenmodes in Matter. Van Der Waals-London and Casimir Forces

A Predictive Model for Monolayer‐Selective Metal‐Mediated MoS2 Exfoliation Incorporating Electrostatics

Contact Info

Product

Resources

About

A Predictive Model for Monolayer‐Selective Metal‐Mediated MoS₂ Exfoliation Incorporating Electrostatics