6533b7d0fe1ef96bd125a314
RESEARCH PRODUCT
Evolution of structural and electronic properties of TiSe2 under high pressure
Resta SusiloYukai ZhuangNing DaiClaudio CazorlaSaadah Abdul RahmanDaniel ErrandoneaHajra SaqibYanwei HuangBin ChenYongsheng Zhaosubject
DiffractionSuperconductivityPhase transitionSuperconductivityMaterials scienceCondensed matter physics:Física [Àrees temàtiques de la UPC]Transition metalPhase (matter)General Materials SciencePhysical and Theoretical ChemistrySuperconductivitatCharge density waveMonoclinic crystal systemPhase diagramdescription
A pressure-induced structural phase transition and its intimate link with the superconducting transition was studied for the first time in TiSe2 up to 40 GPa at room temperature using X-ray diffraction, transport measurement, and first-principles calculations. We demonstrate the occurrence of a first-order structural phase transition at 4 GPa from the standard trigonal structure (S.G.P3¯m1) to another trigonal structure (S-G-P3¯c1). Additionally, at 16 GPa, the P3¯c1 phase spontaneously transforms into a monoclinic C2/m phase, and above 24 GPa, the C2/m phase returns to the initial P3¯m1 phase. Electrical transport results show that metallization occurs above 6 GPa. The charge density wave observed at ambient pressure is suppressed upon compression up to 2 GPa with the emergence of superconductivity at 2.5 GPa, with a critical temperature (Tc) of 2 K. A structural transition accompanies the emergence of superconductivity that persists up to 4 GPa. The results demonstrate that the pressure-induced phase transitions explored by the experiments along with the theoretical predictions may open the door to a new path for searching and controlling the phase diagrams of transition metal dichalcogenides. C.C. acknowledges support from the Spanish Ministry of Science, Innovation, and Universities under the “Ramon y Cajal” fellowship RYC2018-024947-I. Peer Reviewed
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2021-10-14 |