Litcius/Paper detail

Higher-spin gravity and torsion on quantized space-time in matrix models

Harold C. Steinacker

2020Journal of High Energy Physics21 citationsDOIOpen Access PDF

Abstract

A bstract A geometric formalism is developed which allows to describe the non-linear regime of higher-spin gravity emerging on a cosmological quantum space-time in the IKKT matrix model. The vacuum solutions are Ricci-flat up to an effective vacuum energy- momentum tensor quadratic in the torsion, which arises from a Weitzenböck-type higher spin connection. Torsion is expected to be significant only at cosmic scales and around very massive objects, and could behave like dark matter. A non-linear equation for the torsion tensor is found, which encodes the Yang-Mills equations of the matrix model. The metric and torsion transform covariantly under a higher-spin generalization of volume-preserving diffeomorphisms, which arises from the gauge invariance of the matrix model.

Topics & Concepts

PhysicsTorsion (gastropod)Mathematical physicsClassical mechanicsQuantum gravityQuadratic equationGauge theoryGravitationCosmic stringFormalism (music)S-matrixSpin connectionQuantum field theoryCosmologyTensor (intrinsic definition)Theoretical physicsQuantum mechanicsFriedmann–Lemaître–Robertson–Walker metricEigenvalues and eigenvectorsMatrix (chemical analysis)Semiclassical gravityState-transition matrixField equationf(R) gravityVacuum stateTensor densityCosmological modelQuantumNoncommutative and Quantum Gravity TheoriesCosmology and Gravitation TheoriesAlgebraic and Geometric Analysis