New Quantum Spin Perspective and Geometrical Operators of Quantum Geometry

TL;DR

This paper introduces a novel perspective on quantum spin incorporating fundamental constants, modifies geometric operators in quantum geometry, and suggests a self-correcting mechanism at quantum gravity scales that maintains invariance of key constants.

Contribution

It proposes a new quantum spin perspective integrating Planck constants into geometric operators, leading to a modified framework for quantum geometry and insights into scale invariance.

Findings

Area operator spectrum is discrete and increases with the square of quantum number n.

The new perspective suggests a self-balance mechanism maintaining invariance of fundamental constants.

Provides a potential explanation for smooth transition from Planck scale to atomic scale.

Abstract

In this paper, we propose a new perspective of quantum spin (angular momentum) in which the Boltzmann constant \(k_{\beta}\), Planck temperature \(T_{P}\), Planck mass \(m_{P}\) and Planck area \(l_{P}^{2}\) are the integral part of the total angular momentum \(J\). With the aid of this new perspective, we modify the equation of the area and volume operator. In the quantum geometry, for \(SO(3)\) group, the angular momentum operators \(J^{k}\) is the \(k\)th Lie group generator \(T^{k}\); hence, \(T^{k} \equiv J^{k}\). Therefore, new perspective of quantum spin can be directly applicable to quantum geometry. From data, the value of the area operator \(\hat{A}_{S}\) increases with \(n^{2}\) in discrete way that suggests discrete spectrum of the area operator similar to the actual formula of the area operator. This perspective provides an auto-correct or auto-balance mechanism within the equation of these geometrical operators. At the quantum gravity scale, it means that the mutual small change in \(T_{P}\), \(m_{P}\), and \(l_{P}^{2}\) occur in such a way that \(\hbar\), \(l_{P}\) and \(\hat{A}_{S}\) and \( \hat{V}_{S}\) remain invariant for a value of \(j_{i}\). The constancy of the reduced Planck constant \(\hbar\) in the geometrical operators can provide a way through which smooth transition of the Planck scale to the nuclear or the atomic scale can be understood.