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Main Authors: Kuttruff, Joel, Mandal, Ritwika, Servol, Marina, Mariette, Céline, Tokoro, Hiroko, Ohkoshi, Shin-ichi, Sopracase, Rodolphe, Cailleau, Hervé, Cario, Laurent, Janod, Etienne, Lorenc, Maciej, Phuoc, Vinh Ta
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.14415
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author Kuttruff, Joel
Mandal, Ritwika
Servol, Marina
Mariette, Céline
Tokoro, Hiroko
Ohkoshi, Shin-ichi
Sopracase, Rodolphe
Cailleau, Hervé
Cario, Laurent
Janod, Etienne
Lorenc, Maciej
Phuoc, Vinh Ta
author_facet Kuttruff, Joel
Mandal, Ritwika
Servol, Marina
Mariette, Céline
Tokoro, Hiroko
Ohkoshi, Shin-ichi
Sopracase, Rodolphe
Cailleau, Hervé
Cario, Laurent
Janod, Etienne
Lorenc, Maciej
Phuoc, Vinh Ta
contents Correlated transition metal oxides present exciting prospects as switches or memory and storage devices owing to the possibility to control electronic properties using various external stimuli. While their complex behaviour is known to stem from interplay between electronic correlations, atomic structure and orbital physics, they remain poorly understood on the microscopic level. Here, we investigate such origins as a function of temperature and pressure in the transition metal oxide Ti3O5. We find that the insulating room-temperature phase is characterized by one-dimensional zig-zag chains composed by two types of titanium dimers forming orbital selective valence bonds. At the thermal phase transition, one type of titanium dimer breaks up, resulting in an insulator to metal transition with a large orbital repopulation between the two states. Moreover, optical spectroscopy reveals that an additional pressure-driven insulator to metal transition occurs in Ti3O5 at room temperature. The phenomenology of this novel pressure-induced metallic transition is completely different from the insofar studied transitions and results from a competition between intra- and inter-dimer hopping. Our combined results suggest that Ti3O5 is a prototypical correlated transition metal oxide, where both correlations as well as orbital interactions need to be considered to fully understand the evolution of the electronic states.
format Preprint
id arxiv_https___arxiv_org_abs_2604_14415
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Two pathways to break the insulating state in a correlated transition metal oxide
Kuttruff, Joel
Mandal, Ritwika
Servol, Marina
Mariette, Céline
Tokoro, Hiroko
Ohkoshi, Shin-ichi
Sopracase, Rodolphe
Cailleau, Hervé
Cario, Laurent
Janod, Etienne
Lorenc, Maciej
Phuoc, Vinh Ta
Strongly Correlated Electrons
Correlated transition metal oxides present exciting prospects as switches or memory and storage devices owing to the possibility to control electronic properties using various external stimuli. While their complex behaviour is known to stem from interplay between electronic correlations, atomic structure and orbital physics, they remain poorly understood on the microscopic level. Here, we investigate such origins as a function of temperature and pressure in the transition metal oxide Ti3O5. We find that the insulating room-temperature phase is characterized by one-dimensional zig-zag chains composed by two types of titanium dimers forming orbital selective valence bonds. At the thermal phase transition, one type of titanium dimer breaks up, resulting in an insulator to metal transition with a large orbital repopulation between the two states. Moreover, optical spectroscopy reveals that an additional pressure-driven insulator to metal transition occurs in Ti3O5 at room temperature. The phenomenology of this novel pressure-induced metallic transition is completely different from the insofar studied transitions and results from a competition between intra- and inter-dimer hopping. Our combined results suggest that Ti3O5 is a prototypical correlated transition metal oxide, where both correlations as well as orbital interactions need to be considered to fully understand the evolution of the electronic states.
title Two pathways to break the insulating state in a correlated transition metal oxide
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2604.14415