The first part develops an abstract mathematical framework for computing topological invariants of quantum systems using finite spectral data, and provides a conceptual foundation for the odd spectral localiser introduced by Loring and Schulz-Baldes. To this end, we employ E-theory, a bivariant K-theory introduced by Connes and Higson. This framework also allows for a generalisation of the spectral localiser to the Hilbert module setting, thereby enabling finite-rank computations of the topological invariants associated with families of operators.

The second part of the dissertation further develops C*-algebraic models of aperiodic topological materials, and explicitly describes the comparison maps between them. This yields a characterisation of the robustness of topological phases and their invariants, determined by their stability under perturbations.  We also provide alternative dynamical descriptions of one-dimensional aperiodic topological materials, and interpret the Cuntz-Pimsner model of Bourne and Mesland as a topological graph C*-algebra.

We introduce an inductive limit C*-algebra, called the symmetry-breaking Roe C*-algebra, which encodes the symmetry-breaking processes of lattices.  Its K-theory accommodates both strong and weak topological phases, and distinguishes them by divisibility. This allows us to interpret strong topological phases as those that are invariant under symmetry-breaking processes, corresponding to the independence from the specific microscopic partitioning of the material into unit cells.

• bivariant k-theory
• coarse geometry
• delone sets and aperiodic tilings
• groupoid c*-algebras
• noncommutative geometry
• spectral localisers
• topological insulator

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