This research paper presents a novel mathematical framework based on C*-algebras and operator K-theory to explain and classify higher-order bulk-boundary correspondences in topological insulators and superconductors.
Bibliographic Information: Ojito, D. P., Prodan, E., & Stoiber, T. (2024). C∗-framework for higher-order bulk-boundary correspondences. arXiv:2406.04226v2 [math-ph].
Research Objective: The paper aims to provide a rigorous mathematical foundation for understanding and predicting the emergence of topologically protected electronic states at corners, hinges, and other lower-dimensional boundaries in crystalline topological materials.
Methodology: The authors utilize the framework of C*-algebras, specifically groupoid C*-algebras, to model the dynamics of electrons in infinite crystals with boundaries. They construct a filtration of the groupoid's unit space based on the crystal's geometry and symmetry, leading to a spectral sequence in twisted equivariant K-theory.
Key Findings: The paper demonstrates that the differentials in this spectral sequence directly relate the topological invariants of the bulk material to the possible existence and properties of higher-order boundary states. This connection provides a systematic way to classify and predict higher-order bulk-boundary correspondences.
Main Conclusions: The authors conclude that higher-order bulk-boundary correspondence is a robust phenomenon protected by the interplay of spectral gaps and crystalline symmetries. The developed C*-algebraic framework offers a powerful tool to rigorously study and classify these correspondences.
Significance: This research significantly advances the mathematical understanding of topological phases of matter. It provides a rigorous framework for studying higher-order bulk-boundary correspondences, which are of great interest in condensed matter physics and materials science.
Limitations and Future Research: The paper focuses on the one-particle sector and specific geometries. Future research could explore extensions to many-body systems and more complex crystal structures. Additionally, investigating the interplay of this framework with other approaches to higher-order topology could yield further insights.
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