Quantum vacuum, dark matter, dark energy and spontaneous supersymmetry breaking

TL;DR

This paper explores how vacuum condensates in various physical contexts can contribute to dark energy, dark matter, and spontaneous supersymmetry breaking, linking quantum vacuum phenomena to cosmological mysteries.

Contribution

It demonstrates that vacuum condensates from thermal states, curved space-time, and mixed particles can induce dark components and supersymmetry breaking within a supersymmetric framework.

Findings

Vacuum condensates can generate non-trivial dark energy and dark matter components.

Condensates from thermal states and curved space-time induce supersymmetry breaking.

The study connects quantum vacuum phenomena with cosmological dark components.

Abstract

We study the vacuum condensate characterizing many physical phenomena. We show that such a condensate may leads to non-trivial components of the dark energy and of the dark matter and may induces the spontaneous supersymmetry breaking, in a supersymmetric context. In particular, we consider the condensate induced by thermal states, fields in curved space-time and mixed particles.