The initial work on this project centered on understanding the microscopic origin of both superconductivity and charge order in kagome metals. This understanding is an essential step in describing the possible topological properties of the kagome metals. Specifically, I described the types of charge order possible in the kagome metals and how these may arise, including a detailed description of how to design experiments to unambiguously detect and distinguish the charge order present in the actual materials. Subsequently, I conducted a similar study of how superconductivity arises in these materials and how this may lead to topological phenomena. This includes detailed considerations of how superconductivity is affected by disorder and details of the electronic structure and provides important predictions for the possible superconducting states observed in the kagome metals, alongside their topological properties.
In summary, the action resulted in the following results:
(1) A detailed description of the charge orders possible in the kagome metals, their possible microscopic origin, and experimental methods to detect these orders. This has been disseminated in the peer-reviewed journal Physical Review B and is freely available. It was also presented at the Gordon Research Seminar 'Superconductivity' conference.
(2) A microscopic derivation of the possible superconducting phases of the kagome metals, including how these are affected by electronic interactions, and which ones may exhibit topological properties. This has been disseminated in the peer-reviewed journal Physical Review B and is freely available.
(3) A comprehensive treatment of how superconductivity is affected by changes in the electronic structure, in particular as a result of straining the material. This helps explain a set of puzzling experiments on the kagome metals and was published as a letter in Physical Review B and is freely available.
(4) A study of how lattice disorder impacts specific superconducting phases in the kagome lattice, including how this impacts the topologically non-trivial variants. The details of the kagome materials result in a surprising robustness of superconductivity to disorder. This was published in Physical Review B and is freely available.