Electromagnetic semitransparent<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mi>δ</mml:mi></mml:math>-function plate: Casimir interaction energy between parallel infinitesimally thin plates

Parashar, Prachi; Milton, Kimball A.; Shajesh, K. V.; Schaden, Martin

doi:10.1103/physrevd.86.085021

Cited by 41 publications

(80 citation statements)

References 30 publications

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“…A similar kind of δ-function plates was analyzed in [20]. Also notice that the derivatives in the last term in (1) are taken only in the parallel space to the surface because of the fixed index in the Levi-Civita tensor:…”

Section: The Modified Photon Propagatormentioning

confidence: 99%

“…The results of these references are apparently disparate but, as a matter of fact, since those works are dealing with different kinds of dielectrics, they are not supposed to match in general. In [20] the authors address a broader class of dielectrics, starting off by defining their dielectric permittivity and magnetic permeability that are both directly proportional to a δ-function, in contrast to the relations (2). On the other hand, although they do not identify which kind of material correspond to their boundary conditions, in [22] the authors couple an external potential to the Maxwell action similar to the the one we used in Eq.…”

Section: Final Remarksmentioning

confidence: 99%

“…The Casimir energy for soft boundaries has recently been studied in [20,22], by means of different methods. The results of these references are apparently disparate but, as a matter of fact, since those works are dealing with different kinds of dielectrics, they are not supposed to match in general.…”

Section: Final Remarksmentioning

confidence: 99%

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Field theoretic description of electromagnetic boundaries

Barone

2014

Eur. Phys. J. C

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In a previous work we formulated a model of semitransparent dielectric surfaces, coupled to the electromagnetic field by means of an effective potential. Here we consider a setup with two dissimilar mirrors, and we compute exactly the correction undergone by the photon propagator due to the presence of both plates. It turns out that this new propagator is continuous all over the space and, in the appropriate limit, coincides with the one used to describe the Casimir effect between perfect conductors. The amended Green function is then used to calculate the Casimir energy between the uniaxial dielectric surfaces described by the model, and a numerical analysis is carried out to highlight the peculiar behavior of the interaction between the mirrors.

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Section: The Modified Photon Propagatormentioning

confidence: 99%

Section: Final Remarksmentioning

confidence: 99%

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Field theoretic description of electromagnetic boundaries

Barone

2014

Eur. Phys. J. C

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“…(1), have been done by Barone and Barone who proposed an enlarged gauge-invariant Maxwell Lagrangian describing the field in the presence of a δ mirror, investigating the interaction between a static charge and a δ mirror [24], and also the static Casimir effect between two δ mirrors [25]. Parashar, Milton, Shajesh and Schaden [26], in a different approach, considered the electric and magnetic properties of an infinitesimally thin mirror by means of the electric permittivity and magnetic permeability described in terms of δ functions, deriving the boundary conditions for the electromagnetic field on the mirror and investigating the Casimir-Polder interaction between an atom and the mirror. The use of δ − δ ′ potentials (δ ′ is the derivative of the Dirac δ) for simulating partially reflecting mirrors, in the context of the static Casimir effect, was considered by Muñoz-Castañeda and Guilarte [27], resulting in a generalization of (1), done by adding a δ ′ term in the potential, namely…”

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confidence: 99%

Dynamical Casimir effect withδ−δ′mirrors

2016

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We calculate the spectrum and the total rate of created particles for a real massless scalar field in 1 + 1 dimensions, in the presence of a partially transparent moving mirror simulated by a Dirac δ − δ ′ point interaction. We show that, for this model, a partially reflecting mirror can produce a larger number of particles in comparison with a perfect one. In the limit of a perfect mirror, our formulas recover those found in the literature for the particle creation by a moving mirror with a Robin boundary condition.

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“…Others have considered the Casimir effect with twodimensional plates [23], however our particular model requires a more material-centered approach (see the supplement [24]). We consider the Casimir force at zero temperature between two parallel plates where at least one is modeled as a two-band spin-orbit coupled material (sufficiently thin to be considered quasi-two dimensional) with a fixed chemical potential and tunable Zeeman splitting due to an external magnetic field.…”

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confidence: 99%

Nonanalytic behavior of the Casimir force across a Lifshitz transition in a spin-orbit-coupled material

2014

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We propose the Casimir effect as a general method to observe Lifshitz transitions in electron systems. The concept is demonstrated with a planar spin-orbit coupled semiconductor in a magnetic field. We calculate the Casimir force between two such semiconductors and between the semiconductor and a metal as a function of the Zeeman splitting in the semiconductor. The Zeeman field causes a Fermi pocket in the semiconductor to form or collapse by tuning the system through a topological Lifshitz transition. We find that the Casimir force experiences a kink at the transition point and noticeably different behaviors on either side of the transition. The simplest experimental realization of the proposed effect would involve a metal-coated sphere suspended from a micro-cantilever above a thin layer of InSb (or another semiconductor with large g-factor). Numerical estimates are provided and indicate that the effect is well within experimental reach. FIG. 1. The geometry typically used in experimental measurements of the Casimir force is a gold coated sphere suspended above a planar plate from a cantilever. We consider a lower plate of indium antimonide with an applied magnetic field.takes the schematic formwhere X = X (1+ X ) is the dressed currentcurrent correlation function for plate X while X is the usual current-current correlator derived in linear response theory -a material dependent quantity related to conductivity. It enters the expression in a crucial way, and thus, features in the frequency-dependent conductivity translate to features in the Casimir force. Being able to tune the Casimir force by modifying a material's electromagnetic response would have important applications for precision gravity experiments [7] and applications to nanotechnology [8].From the other direction, and importantly for the subject of this paper, any change of the Casimir force would be an indication of a change in the material's properties. Special geometries [9] and boundary conditions [10] can change the Casimir force to be repulsive, though with symmetric geometries without time-reversal symmetry breaking, one can not escape an attractive effect [11]. Just as a repulsive effect would be a signature of some time-reversal symmetry breaking (such as in the case of two quantum Hall plates [12] or topological insulators with gapped surface states [13]), other changes in the Casimir force can be attributed to other material properties. For instance, Bimonte and coauthors showed that one can in principle measure the change in Casimir energy between a normal and superconducting state [14]. Additionally, the critical Casimir effect [15] can be used to characterize the phase transition and probe finite-size scaling [16], while the thermal Casimir effect [17] has been used to probe phase transitions [18].

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Electromagnetic semitransparentδ-function plate: Casimir interaction energy between parallel infinitesimally thin plates

Cited by 41 publications

References 30 publications

Field theoretic description of electromagnetic boundaries

Field theoretic description of electromagnetic boundaries

Dynamical Casimir effect withδ−δ′mirrors

Nonanalytic behavior of the Casimir force across a Lifshitz transition in a spin-orbit-coupled material

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