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Main Authors: Picoli, F. D., Diniz, G., Lenzarini, M. P., D'Amico, I., Oliveira, L. N.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.11317
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author Picoli, F. D.
Diniz, G.
Lenzarini, M. P.
D'Amico, I.
Oliveira, L. N.
author_facet Picoli, F. D.
Diniz, G.
Lenzarini, M. P.
D'Amico, I.
Oliveira, L. N.
contents X-ray photoemission from simple metals has been thoroughly studied, experimentally, and theoretically, in the frequency domain. Here we investigate the same problem in the time domain, with the ultimate purpose of improving the numerical renormalization-group method. We focus our study on the time dependence of the photoemission current $\mathcal{F}(t)$, a fidelity, in the terminology of quantum information. To establish benchmarks, we first calculate $\mathcal{F}(t)$ analytically and numerically for a tight-binding model. Analytically, we derive an approximate expression that becomes very precise at large times. Numerically, we diagonalize the tight-binding Hamiltonian and compute $\mathcal{F}(t)$ from its eigenvalues and eigenvectors, a straightforward procedure that covers the segment of the $t$ axis in which the analytical expression is less accurate. The time dependence shows features of physical interest that have received little attention because they are inconspicuous in the frequency domain; the analytical expression provides a simple interpretation and traces them to an unusual form of interference. We then turn to eNRG, a recently proposed real-space variant that is more flexible than Wilson's NRG method, and present two complementary time-dependent algorithms. Comparison with the benchmarks shows that one of the eNRG algorithms yields virtually exact photocurrents with a small fraction of the computational effort to diagonalize the tight-binding Hamiltonian. The second algorithm is computationally less demanding and produces precise results at long times. In contemplation of extensions to correlated-impurity models, we identify sources of deviation and discuss the virtues and drawbacks of the two procedures.
format Preprint
id arxiv_https___arxiv_org_abs_2502_11317
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Time-dependent approach to the X-ray photoemission problem
Picoli, F. D.
Diniz, G.
Lenzarini, M. P.
D'Amico, I.
Oliveira, L. N.
Mesoscale and Nanoscale Physics
Strongly Correlated Electrons
X-ray photoemission from simple metals has been thoroughly studied, experimentally, and theoretically, in the frequency domain. Here we investigate the same problem in the time domain, with the ultimate purpose of improving the numerical renormalization-group method. We focus our study on the time dependence of the photoemission current $\mathcal{F}(t)$, a fidelity, in the terminology of quantum information. To establish benchmarks, we first calculate $\mathcal{F}(t)$ analytically and numerically for a tight-binding model. Analytically, we derive an approximate expression that becomes very precise at large times. Numerically, we diagonalize the tight-binding Hamiltonian and compute $\mathcal{F}(t)$ from its eigenvalues and eigenvectors, a straightforward procedure that covers the segment of the $t$ axis in which the analytical expression is less accurate. The time dependence shows features of physical interest that have received little attention because they are inconspicuous in the frequency domain; the analytical expression provides a simple interpretation and traces them to an unusual form of interference. We then turn to eNRG, a recently proposed real-space variant that is more flexible than Wilson's NRG method, and present two complementary time-dependent algorithms. Comparison with the benchmarks shows that one of the eNRG algorithms yields virtually exact photocurrents with a small fraction of the computational effort to diagonalize the tight-binding Hamiltonian. The second algorithm is computationally less demanding and produces precise results at long times. In contemplation of extensions to correlated-impurity models, we identify sources of deviation and discuss the virtues and drawbacks of the two procedures.
title Time-dependent approach to the X-ray photoemission problem
topic Mesoscale and Nanoscale Physics
Strongly Correlated Electrons
url https://arxiv.org/abs/2502.11317