Fermionic Casimir Energy in Horava-Lifshitz Scenario

TL;DR

This paper explores how Lorentz symmetry violation in the Horava-Lifshitz framework influences the fermionic Casimir effect, revealing significant modifications in energy and force behavior between plates.

Contribution

It introduces a novel analysis of the fermionic Casimir effect under Lorentz violation using the Horava-Lifshitz model with MIT bag boundary conditions.

Findings

Lorentz violation significantly alters Casimir energy and pressure.

The Casimir force can become attractive or repulsive depending on the critical exponent.

The study demonstrates the impact of higher-order derivatives in the modified Dirac equation.

Abstract

In this work, we investigate the violation of Lorentz symmetry through the Casimir effect. The Casimir effect is one of the most intriguing aspects of modern physics, representing a macroscopic quantum-origin force between two neutral conducting surfaces, and it stands as a triumph of Quantum Field Theory. Here, we examine the Casimir effects associated with a massive fermionic quantum field confined in the region between two large and parallel plates within the Horava-Lifshitz framework of Lorentz symmetry violation. To calculate the Casimir energy and consequently the Casimir pressure, we impose a MIT bag boundary condition on two plates, compatible with the higher-order derivative term in the modified Dirac equation. Our results indicate a strong influence of Lorentz violation on the Casimir effect. We observe that the Casimir energy is affected, both in intensity and sign, potentially exhibiting repulsive or attractive force between the plates, depending on the critical exponent associated with the Horava-Lifshitz formalism.