Explaining Mysterious “Shoulder” Raman Band in TiS2 by Temperature-dependent Anharmonicity and Defects

In this study, we comprehensively investigate the shape of Raman spectra in titanium disulfide (TiS2) and its temperature dependence, using first-principles calculations and a rigorous theoretical approach to evaluate the corresponding Raman scattering cross sections. Our analysis includes anharmoni...

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Veröffentlicht in:	Journal of physical chemistry. C 2023-10, Vol.127 (42), p.20870-20880
Hauptverfasser:	Wilczyński, Konrad, Gertych, Arkadiusz P., Zdrojek, Mariusz
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Sprache:	eng
Schlagworte:	C: Physical Properties of Materials and Interfaces
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container_end_page	20880
container_issue	42
container_start_page	20870
container_title	Journal of physical chemistry. C
container_volume	127
creator	Wilczyński, Konrad Gertych, Arkadiusz P. Zdrojek, Mariusz
description	In this study, we comprehensively investigate the shape of Raman spectra in titanium disulfide (TiS2) and its temperature dependence, using first-principles calculations and a rigorous theoretical approach to evaluate the corresponding Raman scattering cross sections. Our analysis includes anharmonicity-induced effects: phonon–phonon interactions and the thermal expansion of the 1T-TiS2 crystal. We aim to establish the origin of a not yet fully understood Raman feature often observed at the high-energy side of the band corresponding to the out-of-plane A1g phonon modecommonly called the “shoulder” band. We show that TiS2 is an example of a counterintuitive situation in which a relatively large anharmonicity of the system and its specific two-phonon density of states can lead to a highly asymmetric A1g bandconsisting of the main band and a high-energy shoulder. Although the presence of the “shoulder” band is confirmed for ideal 1T-TiS2 crystals, we also consider realistic TiS2 systems characterized by the often-reported presence of excess interlayer titanium atoms. According to our simulation, such defects lead to the splitting of the A1g phonon mode, resulting in the formation of a high-energy shoulder independent of the anharmonicity-induced mechanism depicted above. The dependence of the phonon splitting on the amount and spatial distribution of the extra titanium atoms is also investigated.
doi_str_mv	10.1021/acs.jpcc.3c04701
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Although the presence of the “shoulder” band is confirmed for ideal 1T-TiS2 crystals, we also consider realistic TiS2 systems characterized by the often-reported presence of excess interlayer titanium atoms. According to our simulation, such defects lead to the splitting of the A1g phonon mode, resulting in the formation of a high-energy shoulder independent of the anharmonicity-induced mechanism depicted above. 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title	Explaining Mysterious “Shoulder” Raman Band in TiS2 by Temperature-dependent Anharmonicity and Defects
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