Topological states of matter and noncommutative geometry
Abstract
This thesis examines topological states of matter from the perspective of noncommutative
geometry and KK-theory. Examples of such topological states of matter include
the quantum Hall e ect and topological insulators.
For the quantum Hall e ect, we consider a continuous model and show that the
Hall conductance can be expressed in terms of the index pairing of the Fermi projection
of a disordered Hamiltonian with a spectral triple encoding the geometry of
the sample's momentum space. The presence of a magnetic eld means that noncommutative
algebras and methods must be employed. Higher dimensional analogues of
the quantum Hall system are also considered, where the index pairing produces the
`higher-dimensional Chern numbers' in the continuous setting.
Next we consider a discrete quantum Hall system with an edge. We show that
topological properties of observables concentrated at the boundary can be linked to
invariants from a boundary-free model via the Kasparov product. Hence we obtain the
bulk-edge correspondence of the quantum Hall e ect in the language of KK-theory.
Finally we consider topological insulators, which come from imposing (possibly
anti-linear) symmetries on condensed-matter systems and studying the invariants that
are protected by these symmetries. We show how symmetry data can be linked to
classes in real or complex KK-theory. Finally we prove the bulk-edge correspondence
for topological insulator systems by linking bulk and edge systems using the Kasparov
product in KKO-theory.
Description
Citation
Collections
Source
Type
Book Title
Entity type
Access Statement
License Rights
DOI
Restricted until
Downloads
File
Description