Abstract
We consider the Casimir interaction between two spheres in $(D+1)$-dimensional Minkowski spacetime due to the vacuum fluctuations of scalar fields. We consider combinations of Dirichlet and Neumann boundary conditions. The TGTG formula of the Casimir interaction energy is derived. The computations of the T matrices of the two spheres are straightforward. To compute the two G matrices, known as translation matrices, which relate the hyper-spherical waves in two spherical coordinate frames differ by a translation, we generalize the operator approach employed in [IEEE Trans. Antennas Propag. \textbf{36}, 1078 (1988)]. The result is expressed in terms of an integral over Gegenbauer polynomials. Using our expression for the Casimir interaction energy, we derive the large separation and small separation asymptotic expansions of the Casimir interaction energy. In the large separation regime, we find that the Casimir interaction energy is of order $L^{-2D+3}$, $L^{-2D+1}$ and $L^{-2D-1}$ respectively for Dirichlet-Dirichlet, Dirichlet-Neumann and Neumann-Neumann boundary conditions, where $L$ is the center-to-center distance of the two spheres. In the small separation regime, we confirm that the leading term of the Casimir interaction agrees with the proximity force approximation, which is of order $d^{-\frac{D+1}{2}}$, where $d$ is the distance between the two spheres. Another main result of this work is the analytic computations of the next-to-leading order term in the small separation asymptotic expansion. This term is computed using careful order analysis as well as perturbation method. We find that when $D$ is large, the ratio of the next-to-leading order term to the leading order term is linear in $D$, indicating a larger correction at higher dimensions.
Highlights
In the large separation regime, we find that the Casimir interaction energy is of order L−2D+3, L−2D+1 and L−2D−1 respectively for Dirichlet-Dirichlet, Dirichlet-Neumann and Neumann-Neumann boundary conditions, where L is the centerto-center distance of the two spheres
In the small separation regime, we confirm that the leading term of the Casimir interaction agrees with the proximity force approximation, which is of order d−
We find that the leading contribution to the large separation asymptotic behavior of the Casimir interaction energy comes from lower l as well as smallest possible s, i.e., s = 0
Summary
We use the hyper-spherical coordinate system: x1 =r cos θ1 x2 =r sin θ1 cos θ2. It is easy to see that this formalism does not depend on the dimension of spacetime and the type of quantum field involved It can be applied for Casimir interaction in (D + 1)-dimensional spacetime. KD) in hyper-spherical coordinates: k1 =k cos θ1k, k2 =k sin θ1k cos θ2k, kD−1 =k sin θ1k . Since jν(z) and h(ν1)(z) satisfies the same differential equation, it follows that φomut(x, k) =ilCloutHm(∂)h(01)(kr). As in [38], we express the integration over k⊥ in polar coordinates k2 =k⊥ cos θ2k, k3 =k⊥ sin θ2k cos θ3k,. The Casimir interaction energy between the two spheres are given by c∞ ECas = 2π 0 dκTr ln (1 − M(κ)) ,.
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