Add to ORKGWe present a new method to compute quantum energies in presence of a background field. The method is based on the string-inspired worldline approach to quantum field theory and its numerical realization with Monte-Carlo techniques. Our procedure is applied to the study of the Casimir force between rigid bodies induced by a fluctuating real scalar field. We test our method with the classic parallel-plate configuration and study curvature effects quantitatively for the sphere-plate configuration. The numerical estimates are compared with the ``proximity force approximation''. Sizable curvature effects are found for a distance-to-curvature-radius ratio of a/R>0.02
This paper continues the investigation of the Casimir effect withthe use of the algebraic formulatio...
We study the Casimir interaction between a sphere of radius R separated by a distance L from a plane...
The prototypical Casimir effect arises when a scalar field is confined between parallel Dirich-let b...
We present new results for Casimir forces between rigid bodies which impose Dirichlet boundary condi...
We present improved worldline numerical algorithms for high-precision calculations of Casimir intera...
The Casimir effect refers to the primarily attractive force between material bodies due to quantum f...
We employ worldline numerics to study Casimir effect and Gross-Neveu model. In this approach, the qu...
Casimir interactions are interactions induced by quantum vacuum fluctuations and thermal fluctuation...
We present a simple formalism for the evaluation of the Casimir energy for two spheres and a sphere ...
We present a simple formalism for the evaluation of the Casimir energy for two spheres and a sphere ...
A novel approach for calculating Casimir forces between periodically deformed objects is developed. ...
We reconsider the Casimir effect for the massless conformal scalar field in a ''half Einstein univer...
The Casimir force between two objects is notoriously difficult to calculate in anything other than p...
The Casimir force between two objects is notoriously difficult to calculate in anything other than p...
The proximity force approximation (PFA) relates the interaction between closely spaced, smoothly cur...
This paper continues the investigation of the Casimir effect withthe use of the algebraic formulatio...
We study the Casimir interaction between a sphere of radius R separated by a distance L from a plane...
The prototypical Casimir effect arises when a scalar field is confined between parallel Dirich-let b...
We present new results for Casimir forces between rigid bodies which impose Dirichlet boundary condi...
We present improved worldline numerical algorithms for high-precision calculations of Casimir intera...
The Casimir effect refers to the primarily attractive force between material bodies due to quantum f...
We employ worldline numerics to study Casimir effect and Gross-Neveu model. In this approach, the qu...
Casimir interactions are interactions induced by quantum vacuum fluctuations and thermal fluctuation...
We present a simple formalism for the evaluation of the Casimir energy for two spheres and a sphere ...
We present a simple formalism for the evaluation of the Casimir energy for two spheres and a sphere ...
A novel approach for calculating Casimir forces between periodically deformed objects is developed. ...
We reconsider the Casimir effect for the massless conformal scalar field in a ''half Einstein univer...
The Casimir force between two objects is notoriously difficult to calculate in anything other than p...
The Casimir force between two objects is notoriously difficult to calculate in anything other than p...
The proximity force approximation (PFA) relates the interaction between closely spaced, smoothly cur...
This paper continues the investigation of the Casimir effect withthe use of the algebraic formulatio...
We study the Casimir interaction between a sphere of radius R separated by a distance L from a plane...
The prototypical Casimir effect arises when a scalar field is confined between parallel Dirich-let b...