GLT matrix-sequences and few emblematic applications
Abstract
This thesis advances the spectral theory of structured matrix-sequences within the framework of Generalized Locally Toeplitz (GLT) *-algebras, focusing on the geometric mean of Hermitian positive definite (HPD) GLT sequences and its applications in mathematical physics. For two HPD sequences \An\n GLT and \Bn\n GLT in the same d-level, r-block GLT *-algebra, we prove that when and commute, the geometric mean sequence \G(An,Bn)\n is GLT with symbol ()1/2, without requiring invertibility of either symbol, settling [Conjecture 10.1]garoni2017 for r=1, d1. In degenerate cases, we identify conditions ensuring \G(An,Bn)\n GLT G(,). For r>1 and non-commuting symbols, numerical evidence shows the sequence still admits a spectral symbol, indicating maximality of the commuting result. Numerical experiments in scalar and block settings confirm the theory and illustrate spectral behaviour. We also sketch the extension to k2 sequences via the Karcher mean, obtaining \G(An(1),…,An(k))\n GLT G(1,…,k). Finally, we apply the GLT framework to mean-field quantum spin systems, showing that matrices from the quantum Curie--Weiss model form GLT sequences with explicitly computable spectral distributions.
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