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We introduce non-Abelian tensor Berry connections to study topological phases in multiband systems. This new framework unifies diverse topological models and reveals novel gauge fields in condensed matter physics.

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Area of Science:

  • Condensed Matter Physics
  • Theoretical Physics
  • Materials Science

Background:

  • Topological phases in multiband systems are crucial for novel quantum phenomena.
  • Existing theories often struggle to unify diverse topological classifications.
  • The emergence of gauge fields in condensed matter is a key area of research.

Purpose of the Study:

  • Introduce and apply non-Abelian tensor Berry connections for topological phases.
  • Generalize existing Berry connection formalisms to multiband systems.
  • Provide a unifying framework for classifying topological matter.

Main Methods:

  • Constructing non-Abelian antisymmetric tensor gauge fields from momentum-space Higgs fields.
  • Deriving topological invariants using winding numbers associated with Higgs fields.
  • Developing higher-dimensional Berry-Zak phases for topological characterization.

Main Results:

  • Conventional topological invariants for 2D topological insulators and 3D Dirac semimetals are derived.
  • Higher-dimensional Berry-Zak phases are constructed and applied to classify various gapped and gapless systems.
  • A novel class of models supporting space-time inversion and chiral symmetries is identified.

Conclusions:

  • Non-Abelian tensor Berry connections offer a unifying framework for multiband topological systems.
  • This formalism sheds light on the emergence of non-Abelian gauge fields in condensed matter.
  • The findings have direct implications for discovering new topological phases in solid-state and synthetic systems.