Superconductor-insulator transitions in three-dimensional indium-oxide at high pressures

Bar Hen*, Victor Shelukhin, Eran Greenberg, Gregory Kh Rozenberg, Aharon Kapitulnik, Alexander Palevski

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

2 Scopus citations

Abstract

Experiments investigating magnetic-field-tuned superconductor-insulator transition (HSIT) mostly focus on two-dimensional material systems where the transition and its proximate ground-state phases, often exhibit features that are seemingly at odds with the expected behavior. Here we present a complementary study of a three-dimensional pressure-packed amorphous indium-oxide (InOx) powder where granularity controls the HSIT. Above a low threshold pressure of ∼0.2 GPa, vestiges of superconductivity are detected, although neither a true superconducting transition nor insulating behavior are observed. Instead, a saturation at very high resistivity at low pressure is followed by saturation at very low resistivity at higher pressure. We identify both as different manifestations of anomalous metallic phases dominated by superconducting fluctuations. By analogy with previous identification of the low resistance saturation as a 'failed superconductor', our data suggests that the very high resistance saturation is a manifestation of a 'failed insulator'. Above a threshold pressure of ∼6 GPa, the sample becomes fully packed, and superconductivity is robust, with T C tunable with pressure. A quantum critical point at P C ∼ 25 GPa marks the complete suppression of superconductivity. For a finite pressure below P C, a magnetic field is shown to induce a HSIT from a true zero-resistance superconducting state to a weakly insulating behavior. Determining the critical field, H C, we show that similar to the 2D behavior, the insulating-like state maintains a superconducting character, which is quenched at higher field, above which the magnetoresistance decreases to its fermionic normal state value.

Original languageEnglish
Article number135402
JournalJournal of Physics Condensed Matter
Volume34
Issue number13
DOIs
StatePublished - 30 Mar 2022

Funding

FundersFunder number
National Science Foundation—Earth SciencesEAR – 1634415
National Science Foundation1748/20 227/16, NSF-DMR- 1808385
U.S. Department of Energy
Office of Science
Argonne National LaboratoryDE-AC02-06CH11357

    Keywords

    • electronic transport
    • high pressure
    • magnetoresistance
    • superconductor to insulator transition quantum phase transition
    • x-ray diffraction

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