Fermi surface of PtCoO2 from quantum oscillations and electronic structure calculations

The delafossite series of layered oxides includes some of the highest conductivity metals ever discovered. Of these, PtCoO2, with a room-temperature resistivity of 1.8 μΩcm for in-plane transport, is the most conducting of all. The high conduction takes place in triangular lattice Pt layers, separat...

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Published in:Physical review. B 2020-05, Vol.101 (19), p.1
Main Authors: Arnold, F, Naumann, M, Rosner, H, Kikugawa, N, Graf, D, Balicas, L, Terashima, T, Uji, S, Takatsu, H, Khim, S, Mackenzie, A P, Hassinger, E
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Language:English
Subjects:
Cobalt
Conduction
Electron spin
Electronic structure
Fermi surfaces
First principles
Free electrons
Frequency analysis
Mathematical analysis
Oscillations
Platinum
Room temperature
Spin-orbit interactions
Warping
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container_issue 19
container_start_page 1
container_title Physical review. B
container_volume 101
creator Arnold, F
Naumann, M
Rosner, H
Kikugawa, N
Graf, D
Balicas, L
Terashima, T
Uji, S
Takatsu, H
Khim, S
Mackenzie, A P
Hassinger, E
description The delafossite series of layered oxides includes some of the highest conductivity metals ever discovered. Of these, PtCoO2, with a room-temperature resistivity of 1.8 μΩcm for in-plane transport, is the most conducting of all. The high conduction takes place in triangular lattice Pt layers, separated by layers of Co-O octahedra, and the electronic structure is determined by the interplay of the two types of layers. We present a detailed study of quantum oscillations in PtCoO2, at temperatures down to 35 mK and magnetic fields up to 30 T. As for PdCoO2 and PdRhO2, the Fermi surface consists of a single cylinder with mainly Pt character and an effective mass close to the free-electron value. Due to Fermi-surface warping, two close-lying high frequencies are observed. Additionally, a pronounced difference frequency appears. By analyzing the detailed angular dependence of the quantum-oscillation frequencies, we establish the warping parameters of the Fermi surface. We compare these results to the predictions of first-principles electronic-structure calculations including spin-orbit coupling on Pt and Co and on-site correlation U on Co, and hence demonstrate that electronic correlations in the Co-O layers play an important role in determining characteristic features of the electronic structure of PtCoO2.
doi_str_mv 10.1103/PhysRevB.101.195101
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source American Physical Society:Jisc Collections:APS Read and Publish 2023-2025 (reading list)
subjects Cobalt
Conduction
Electron spin
Electronic structure
Fermi surfaces
First principles
Free electrons
Frequency analysis
Mathematical analysis
Oscillations
Platinum
Room temperature
Spin-orbit interactions
Warping
title Fermi surface of PtCoO2 from quantum oscillations and electronic structure calculations
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