Zero-point energy of solids from vacuum fluctuation and quantum geometric force

TL;DR

This paper demonstrates that vacuum electromagnetic fluctuations induce a volume-scaling zero-point energy in solids, leading to measurable quantum geometric forces in superconducting circuits, revealing a new macroscopic quantum effect.

Contribution

It introduces the concept of quantum geometric force arising from zero-point energy in solids, connecting quantum geometry with observable macroscopic forces.

Findings

Zero-point energy scales with the volume of solids.

Quantum geometric force can be measured via superconducting circuits.

Zero-point energy depends on the circuit's capacitor properties.

Abstract

We show that quantum fluctuations of electromagnetic fields induce an additional zero-point energy in solids, which scales with the volume. For insulators, the zero-point energy density is proportional to quantum fluctuation of electric polarization in the many-body ground state, a fundamental quantum geometric property of solids known as the quantum weight. Although the zero-point energy does not affect the dynamics of the electromagnetic fields, when the fields are produced by a superconducting LC circuit, the zero-point energy contributes to a repulsive force between the circuit and the material. In addition, since zero-point energy depends on the circuit's capacitor, it yields a measurable static force acting on the capacitor plates, which we call quantum geometric force. The proposed effects provide direct experimental access to the many-body quantum geometry and reveal a new macroscopic quantum effect in solids induced by vacuum fluctuation.