Cycles Cohomology and Geometrical Correspondences of Derived Categories to Field Equations

Francisco Bulnes

doi:10.24297/jam.v14i2.7581

Authors

Francisco Bulnes IINAMEI International Advanced Research in Mathematics and Engineering, Chalco, Mexico

DOI:

https://doi.org/10.24297/jam.v14i2.7581

Keywords:

Cycles Cohomology, Field Equations, Field Ramifications, Generalized Verma Modules, Geometrical Langlands Correspondence, Hecke Category, Moduli Stack, Spec Functors

Abstract

The integral geometry methods are the techniques could be the more naturally applied to study of the characterization of the moduli stacks and solution classes (represented cohomologically) obtained under the study of the kernels of the differential operators of the corresponding field theory equations to the space-time. Then through a functorial process a classification of differential operators is obtained through of the co-cycles spaces that are generalized Verma modules to the space-time, characterizing the solutions of the field equations. This extension can be given by a global Langlands correspondence between the Hecke sheaves category on an adequate moduli stack and the holomorphic bundles category with a special connection (Deligne connection). Using the classification theorem given by geometrical Langlands correspondences are given various examples on the information that the geometrical invariants and dualities give through moduli problems and Lie groups acting.

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References

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