Measuring finite Quantum Geometries via Quasi-Coherent States

Lukas Schneiderbauer, Harold C. Steinacker

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Abstract

We develop a systematic approach to determine and measure numerically the geometry of generic quantum or "fuzzy" geometries realized by a set of finite-dimensional hermitian matrices. The method is designed to recover the semi-classical limit of quantized symplectic spaces embedded in $\mathbb{R}^d$ including the well-known examples of fuzzy spaces, but it applies much more generally. The central tool is provided by quasi-coherent states, which are defined as ground states of Laplace- or Dirac operators corresponding to localized point branes in target space. The displacement energy of these quasi-coherent states is used to extract the local dimension and tangent space of the semi-classical geometry, and provides a measure for the quality and self-consistency of the semi-classical approximation. The method is discussed and tested with various examples, and implemented in an open-source Mathematica package.
Original languageEnglish
Article number285301
Number of pages44
JournalJournal of Physics A: Mathematical and Theoretical
Volume49
Issue number28
DOIs
Publication statusPublished - 31 May 2016

Austrian Fields of Science 2012

  • 103036 Theoretical physics
  • 103019 Mathematical physics

Keywords

  • hep-th
  • GAUGE-THEORY
  • fuzzy spaces
  • quantum geometry
  • FUZZY
  • BRANES
  • matrix models
  • point brane
  • non-commutative geometry
  • MODEL
  • coherent states
  • Fuzzy spaces

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