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Autori principali: Ritarossi, Simone, Apponi, Alice, Castellano, Orlando, Lorenzana, José, Convertino, Domenica, Coletti, Camilla, Lee, Tien-Lin, Offi, Francesco, Ruocco, Alessandro
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2605.12330
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author Ritarossi, Simone
Apponi, Alice
Castellano, Orlando
Lorenzana, José
Convertino, Domenica
Coletti, Camilla
Lee, Tien-Lin
Offi, Francesco
Ruocco, Alessandro
author_facet Ritarossi, Simone
Apponi, Alice
Castellano, Orlando
Lorenzana, José
Convertino, Domenica
Coletti, Camilla
Lee, Tien-Lin
Offi, Francesco
Ruocco, Alessandro
contents Hard-x-ray C 1s photoemission from monolayer graphene probes a regime in which nuclear recoil and intrinsic electronic asymmetry contribute on comparable energy scales to the observed spectral line shape. Here we combine experiment and modeling over the photon-energy range 0.8 keV--8 keV to resolve this interplay quantitatively. A graphene-specific implementation of the Fujikawa--Takata cumulant formalism, based on an anisotropic vibrational density of states constrained by first-principles phonon calculations, captures the expected recoil scaling with photon energy and emission geometry but fails to reproduce the pronounced asymmetric tails of the measured spectra. To overcome this limitation, we introduce an explicit electronic convolution model in which an intrinsic, photon-energy-independent electronic line shape extracted from near-recoilless 0.8 keV data is convolved with a phonon recoil kernel carrying the full dependence on photon energy and emission angle. This approach reproduces both the measured line-shape evolution and the observed centroid shifts across the explored energy range without refitting the spectra at higher photon energies. The results show that recoil in graphene cannot be described by a baseline treatment in which the phonon recoil kernel is combined only with symmetric lifetime broadening, but must be treated together with the intrinsic many-body electronic response of the C 1s line.
format Preprint
id arxiv_https___arxiv_org_abs_2605_12330
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Graphene lattice recoil in hard X-ray photoemission: Experiment and Theory
Ritarossi, Simone
Apponi, Alice
Castellano, Orlando
Lorenzana, José
Convertino, Domenica
Coletti, Camilla
Lee, Tien-Lin
Offi, Francesco
Ruocco, Alessandro
Materials Science
Hard-x-ray C 1s photoemission from monolayer graphene probes a regime in which nuclear recoil and intrinsic electronic asymmetry contribute on comparable energy scales to the observed spectral line shape. Here we combine experiment and modeling over the photon-energy range 0.8 keV--8 keV to resolve this interplay quantitatively. A graphene-specific implementation of the Fujikawa--Takata cumulant formalism, based on an anisotropic vibrational density of states constrained by first-principles phonon calculations, captures the expected recoil scaling with photon energy and emission geometry but fails to reproduce the pronounced asymmetric tails of the measured spectra. To overcome this limitation, we introduce an explicit electronic convolution model in which an intrinsic, photon-energy-independent electronic line shape extracted from near-recoilless 0.8 keV data is convolved with a phonon recoil kernel carrying the full dependence on photon energy and emission angle. This approach reproduces both the measured line-shape evolution and the observed centroid shifts across the explored energy range without refitting the spectra at higher photon energies. The results show that recoil in graphene cannot be described by a baseline treatment in which the phonon recoil kernel is combined only with symmetric lifetime broadening, but must be treated together with the intrinsic many-body electronic response of the C 1s line.
title Graphene lattice recoil in hard X-ray photoemission: Experiment and Theory
topic Materials Science
url https://arxiv.org/abs/2605.12330