Heisenberg groups and noncommutative fluxes
Copyright policy )Heisenberg groups and noncommutative fluxes
We develop a group-theoretical approach to the formulation of generalized abelian gauge theories, such as those appearing in string theory and M-theory. We explore several applications of this approach. First, we show that there is an uncertainty relation which obstructs simultaneous measurement of electric and magnetic flux when torsion fluxes are included. Next we show how to define the Hilbert space of a self-dual field. The Hilbert space is Z2-graded and we show that, in general, self-dual theories (including the RR fields of string theory) have fermionic sectors. We indicate how rational conformal field theories associated to the two-dimensional Gaussian model generalize to (4k+2)-dimensional conformal field theories. When our ideas are applied to the RR fields of string theory we learn that it is impossible to measure the K-theory class of a RR field. Only the reduction modulo torsion can be measured.
68 pp
- The University of Texas at Austin United States
- University of Oxford United Kingdom
- Rutgers, The State University of New Jersey United States
High Energy Physics - Theory, topology, generalized abelian gauge theories, FOS: Physical sciences, String and superstring theories in gravitational theory, String and superstring theories; other extended objects (e.g., branes) in quantum field theory, Supergravity, Yang-Mills and other gauge theories in quantum field theory, uncertainty principle, gauge theory, High Energy Physics - Theory (hep-th), string theory, Ramond-Ramond fields
High Energy Physics - Theory, topology, generalized abelian gauge theories, FOS: Physical sciences, String and superstring theories in gravitational theory, String and superstring theories; other extended objects (e.g., branes) in quantum field theory, Supergravity, Yang-Mills and other gauge theories in quantum field theory, uncertainty principle, gauge theory, High Energy Physics - Theory (hep-th), string theory, Ramond-Ramond fields
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