A new understanding of Einstein-Rosen bridges

TL;DR

This paper offers a novel quantum perspective on Einstein-Rosen bridges, linking quantum effects at horizons to cosmic microwave background anomalies, and aims to unify gravity with quantum mechanics.

Contribution

It introduces a new quantum framework for ER bridges involving geometric superselection sectors and phase space horizons, addressing the original ER puzzle and supporting a unitary QFTCS.

Findings

Quantum effects at horizons involve inverted harmonic oscillators.

Large-scale parity asymmetry observed in cosmic microwave background.

Supports a unitary and observer-compatible quantum description of spacetime.

Abstract

The formulation of quantum field theory in Minkowski spacetime, which emerges from the unification of special relativity and quantum mechanics, is based on treating time as a parameter, assuming a fixed arrow of time, and requiring that field operators commute for spacelike distances. This procedure is questioned here in the context of quantum field theory in curved spacetime (QFTCS). In 1935, Einstein and Rosen (ER), in their seminal paper (Einstein and Rosen 1935 Phys. Rev. 48 73-77), proposed that "a particle in the physical Universe has to be described by mathematical bridges connecting two sheets of spacetime" which involved two arrows of time. Recently proposed direct-sum quantum theory reconciles this ER's vision by introducing geometric superselection sectors associated with the regions of spacetime related by discrete transformations. We further establish that the quantum effects at gravitational horizons involve the physics of quantum inverted harmonic oscillators that have phase space horizons. This new understanding of the ER bridges is not related to classical wormholes, it addresses the original ER puzzle and promises a unitary description of QFTCS, along with observer complementarity. Furthermore, we present compelling evidence for our new understanding of ER bridges in the form of large-scale parity asymmetric features in the cosmic microwave background, which is statistically 650 times stronger than the standard scale-invariant power spectrum from the typical understanding of inflationary quantum fluctuations when compared with the posterior probabilities associated with the model given the data. We finally discuss the implications of this new understanding in combining gravity and quantum mechanics.