Crystal-chemical origins of the ultrahigh conductivity of metallic delafossites

Yi Zhang; Fred Tutt; Guy N. Evans; Prachi Sharma; Greg Haugstad; Ben Kaiser; Justin Ramberger; Samuel Bayliff; Yu Tao; Mike Manno; Javier Garcia-Barriocanal; Vipul Chaturvedi; Rafael M. Fernandes; Turan Birol; William E. Seyfried; Chris Leighton

doi:10.1038/s41467-024-45239-6

Crystal-chemical origins of the ultrahigh conductivity of metallic delafossites

Yi Zhang, Fred Tutt, Guy N. Evans, Prachi Sharma, Greg Haugstad, Ben Kaiser, Justin Ramberger, Samuel Bayliff, Yu Tao, Mike Manno, Javier Garcia-Barriocanal, Vipul Chaturvedi, Rafael M. Fernandes, Turan Birol, William E. Seyfried, Chris Leighton

Research output: Contribution to journal › Article › peer-review

Abstract

Despite their highly anisotropic complex-oxidic nature, certain delafossite compounds (e.g., PdCoO₂, PtCoO₂) are the most conductive oxides known, for reasons that remain poorly understood. Their room-temperature conductivity can exceed that of Au, while their low-temperature electronic mean-free-paths reach an astonishing 20 μm. It is widely accepted that these materials must be ultrapure to achieve this, although the methods for their growth (which produce only small crystals) are not typically capable of such. Here, we report a different approach to PdCoO₂ crystal growth, using chemical vapor transport methods to achieve order-of-magnitude gains in size, the highest structural qualities yet reported, and record residual resistivity ratios (> 440). Nevertheless, detailed mass spectrometry measurements on these materials reveal that they are not ultrapure in a general sense, typically harboring 100s-of-parts-per-million impurity levels. Through quantitative crystal-chemical analyses, we resolve this apparent dichotomy, showing that the vast majority of impurities are forced to reside in the Co-O octahedral layers, leaving the conductive Pd sheets highly pure (∼1 ppm impurity concentrations). These purities are shown to be in quantitative agreement with measured residual resistivities. We thus conclude that a sublattice purification mechanism is essential to the ultrahigh low-temperature conductivity and mean-free-path of metallic delafossites.

Original language	English (US)
Article number	1399
Journal	Nature communications
Volume	15
Issue number	1
Early online date	Feb 15 2024
DOIs	https://doi.org/10.1038/s41467-024-45239-6
State	Published - Dec 2024
Externally published	Yes

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/s41467-024-45239-6License: CC BY

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Zhang, Y., Tutt, F., Evans, G. N., Sharma, P., Haugstad, G., Kaiser, B., Ramberger, J., Bayliff, S., Tao, Y., Manno, M., Garcia-Barriocanal, J., Chaturvedi, V., Fernandes, R. M., Birol, T., Seyfried, W. E., & Leighton, C. (2024). Crystal-chemical origins of the ultrahigh conductivity of metallic delafossites. Nature communications, 15(1), Article 1399. https://doi.org/10.1038/s41467-024-45239-6

Zhang, Y, Tutt, F, Evans, GN, Sharma, P, Haugstad, G, Kaiser, B, Ramberger, J, Bayliff, S, Tao, Y, Manno, M, Garcia-Barriocanal, J, Chaturvedi, V, Fernandes, RM, Birol, T, Seyfried, WE & Leighton, C 2024, 'Crystal-chemical origins of the ultrahigh conductivity of metallic delafossites', Nature communications, vol. 15, no. 1, 1399. https://doi.org/10.1038/s41467-024-45239-6

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title = "Crystal-chemical origins of the ultrahigh conductivity of metallic delafossites",

abstract = "Despite their highly anisotropic complex-oxidic nature, certain delafossite compounds (e.g., PdCoO2, PtCoO2) are the most conductive oxides known, for reasons that remain poorly understood. Their room-temperature conductivity can exceed that of Au, while their low-temperature electronic mean-free-paths reach an astonishing 20 μm. It is widely accepted that these materials must be ultrapure to achieve this, although the methods for their growth (which produce only small crystals) are not typically capable of such. Here, we report a different approach to PdCoO2 crystal growth, using chemical vapor transport methods to achieve order-of-magnitude gains in size, the highest structural qualities yet reported, and record residual resistivity ratios (> 440). Nevertheless, detailed mass spectrometry measurements on these materials reveal that they are not ultrapure in a general sense, typically harboring 100s-of-parts-per-million impurity levels. Through quantitative crystal-chemical analyses, we resolve this apparent dichotomy, showing that the vast majority of impurities are forced to reside in the Co-O octahedral layers, leaving the conductive Pd sheets highly pure (∼1 ppm impurity concentrations). These purities are shown to be in quantitative agreement with measured residual resistivities. We thus conclude that a sublattice purification mechanism is essential to the ultrahigh low-temperature conductivity and mean-free-path of metallic delafossites.",

author = "Yi Zhang and Fred Tutt and Evans, {Guy N.} and Prachi Sharma and Greg Haugstad and Ben Kaiser and Justin Ramberger and Samuel Bayliff and Yu Tao and Mike Manno and Javier Garcia-Barriocanal and Vipul Chaturvedi and Fernandes, {Rafael M.} and Turan Birol and Seyfried, {William E.} and Chris Leighton",

note = "We thank Prof. Xinyuan Zhang for useful advice on ICP-MS analysis. This work was primarily supported by the US Department of Energy through the University of Minnesota (UMN) Center for Quantum Materials, under Grant No. DE-SC0016371 (CL). Parts of this work were carried out in the Characterization Facility, UMN, which receives partial support from the National Science Foundation through the MRSEC (Award Number DMR-2011401) and NNCI (Award Number ECCS-2025124) programs. The Minnesota Supercomputing Institute at UMN provided resources that contributed to the research reported within this paper.",

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doi = "10.1038/s41467-024-45239-6",

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T1 - Crystal-chemical origins of the ultrahigh conductivity of metallic delafossites

AU - Zhang, Yi

AU - Tutt, Fred

AU - Evans, Guy N.

AU - Sharma, Prachi

AU - Haugstad, Greg

AU - Kaiser, Ben

AU - Ramberger, Justin

AU - Bayliff, Samuel

AU - Tao, Yu

AU - Manno, Mike

AU - Garcia-Barriocanal, Javier

AU - Chaturvedi, Vipul

AU - Fernandes, Rafael M.

AU - Birol, Turan

AU - Seyfried, William E.

AU - Leighton, Chris

N1 - We thank Prof. Xinyuan Zhang for useful advice on ICP-MS analysis. This work was primarily supported by the US Department of Energy through the University of Minnesota (UMN) Center for Quantum Materials, under Grant No. DE-SC0016371 (CL). Parts of this work were carried out in the Characterization Facility, UMN, which receives partial support from the National Science Foundation through the MRSEC (Award Number DMR-2011401) and NNCI (Award Number ECCS-2025124) programs. The Minnesota Supercomputing Institute at UMN provided resources that contributed to the research reported within this paper.

PY - 2024/12

Y1 - 2024/12

N2 - Despite their highly anisotropic complex-oxidic nature, certain delafossite compounds (e.g., PdCoO2, PtCoO2) are the most conductive oxides known, for reasons that remain poorly understood. Their room-temperature conductivity can exceed that of Au, while their low-temperature electronic mean-free-paths reach an astonishing 20 μm. It is widely accepted that these materials must be ultrapure to achieve this, although the methods for their growth (which produce only small crystals) are not typically capable of such. Here, we report a different approach to PdCoO2 crystal growth, using chemical vapor transport methods to achieve order-of-magnitude gains in size, the highest structural qualities yet reported, and record residual resistivity ratios (> 440). Nevertheless, detailed mass spectrometry measurements on these materials reveal that they are not ultrapure in a general sense, typically harboring 100s-of-parts-per-million impurity levels. Through quantitative crystal-chemical analyses, we resolve this apparent dichotomy, showing that the vast majority of impurities are forced to reside in the Co-O octahedral layers, leaving the conductive Pd sheets highly pure (∼1 ppm impurity concentrations). These purities are shown to be in quantitative agreement with measured residual resistivities. We thus conclude that a sublattice purification mechanism is essential to the ultrahigh low-temperature conductivity and mean-free-path of metallic delafossites.

AB - Despite their highly anisotropic complex-oxidic nature, certain delafossite compounds (e.g., PdCoO2, PtCoO2) are the most conductive oxides known, for reasons that remain poorly understood. Their room-temperature conductivity can exceed that of Au, while their low-temperature electronic mean-free-paths reach an astonishing 20 μm. It is widely accepted that these materials must be ultrapure to achieve this, although the methods for their growth (which produce only small crystals) are not typically capable of such. Here, we report a different approach to PdCoO2 crystal growth, using chemical vapor transport methods to achieve order-of-magnitude gains in size, the highest structural qualities yet reported, and record residual resistivity ratios (> 440). Nevertheless, detailed mass spectrometry measurements on these materials reveal that they are not ultrapure in a general sense, typically harboring 100s-of-parts-per-million impurity levels. Through quantitative crystal-chemical analyses, we resolve this apparent dichotomy, showing that the vast majority of impurities are forced to reside in the Co-O octahedral layers, leaving the conductive Pd sheets highly pure (∼1 ppm impurity concentrations). These purities are shown to be in quantitative agreement with measured residual resistivities. We thus conclude that a sublattice purification mechanism is essential to the ultrahigh low-temperature conductivity and mean-free-path of metallic delafossites.

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Crystal-chemical origins of the ultrahigh conductivity of metallic delafossites

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