There is no vacuum zero-point energy in our universe for massive particles within the scope of relativistic quantum mechanics

TL;DR

This paper demonstrates that, within relativistic quantum mechanics and the Dirac oscillator model, massive particles do not possess a zero-point energy, challenging traditional assumptions and offering insights into the cosmological constant problem.

Contribution

It shows that zero-point energy for massive particles does not exist in the Dirac oscillator framework, contrasting with the Schrödinger model and addressing cosmological implications.

Findings

No zero-point energy in Dirac oscillator model.

Wave function can be static without violating principles.

Implications for the cosmological constant problem.

Abstract

It was long believed that there is a zero-point energy in the form of h\omega/2 for massive particles, which is obtained from Schr\"odinger equation for the harmonic oscillator model. In this paper, it is shown, by the Dirac oscillator, that there is no such a zero-point energy. It is argued that when a particle's wave function can spread in the whole space, it can be static. This does neither violate wave-particle duality nor uncertainty relationship. Dirac equation correctly describes physical reality, while Schr\"odinger equation does not when it is not the nonrelativistic approximation of Dirac equation with a certain model. The conclusion that there is no zero-point energy in the form of h\omega/2 is applied to solve the famous cosmological constant problem for massive particles.