Fermi surface transformation at the pseudogap critical point of a cuprate superconductor

Yawen Fang; Gaël Grissonnanche; Anaëlle Legros; Simon Verret; Francis Laliberté; Clément Collignon; Amirreza Ataei; Maxime Dion; Jianshi Zhou; David Graf; Michael J. Lawler; Paul A. Goddard; Louis Taillefer; B. J. Ramshaw

doi:10.1038/s41567-022-01514-1

Fermi surface transformation at the pseudogap critical point of a cuprate superconductor

Yawen Fang
, Gaël Grissonnanche
, Anaëlle Legros
, Simon Verret
, Francis Laliberté
, Clément Collignon
, Amirreza Ataei
, Maxime Dion
, Jianshi Zhou
, David Graf
, Michael J. Lawler
, Paul A. Goddard
, Louis Taillefer
, B. J. Ramshaw

Physics

Binghamton University

Cornell University
Université de Sherbrooke
Université Paris-Saclay
University of Texas at Austin
National High Magnetic Field Laboratory
University of Warwick
Canadian Institute for Advanced Research

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

37 Scopus citations

Abstract

The nature of the pseudogap phase remains a major puzzle in our understanding of cuprate high-temperature superconductivity. Whether or not this metallic phase is defined by any of the reported broken symmetries, the topology of its Fermi surface remains a fundamental open question. Here we use angle-dependent magnetoresistance (ADMR) to measure the Fermi surface of the La_1.6–xNd_0.4Sr_xCuO₄ cuprate. Outside the pseudogap phase, we fit the ADMR data and extract a Fermi surface geometry that is in excellent agreement with angle-resolved photoemission data. Within the pseudogap phase, the ADMR is qualitatively different, revealing a transformation of the Fermi surface. We can rule out changes in the quasiparticle lifetime as the sole cause of this transformation. We find that our data are most consistent with a pseudogap Fermi surface that consists of small, nodal hole pockets, thereby accounting for the drop in carrier density across the pseudogap transition found in several cuprates.

Original language	English
Pages (from-to)	558-564
Number of pages	7
Journal	Nature Physics
Volume	18
Issue number	5
DOIs	https://doi.org/10.1038/s41567-022-01514-1
State	Published - May 2022

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title = "Fermi surface transformation at the pseudogap critical point of a cuprate superconductor",

abstract = "The nature of the pseudogap phase remains a major puzzle in our understanding of cuprate high-temperature superconductivity. Whether or not this metallic phase is defined by any of the reported broken symmetries, the topology of its Fermi surface remains a fundamental open question. Here we use angle-dependent magnetoresistance (ADMR) to measure the Fermi surface of the La1.6–xNd0.4SrxCuO4 cuprate. Outside the pseudogap phase, we fit the ADMR data and extract a Fermi surface geometry that is in excellent agreement with angle-resolved photoemission data. Within the pseudogap phase, the ADMR is qualitatively different, revealing a transformation of the Fermi surface. We can rule out changes in the quasiparticle lifetime as the sole cause of this transformation. We find that our data are most consistent with a pseudogap Fermi surface that consists of small, nodal hole pockets, thereby accounting for the drop in carrier density across the pseudogap transition found in several cuprates.",

author = "Yawen Fang and Ga{\"e}l Grissonnanche and Ana{\"e}lle Legros and Simon Verret and Francis Lalibert{\'e} and Cl{\'e}ment Collignon and Amirreza Ataei and Maxime Dion and Jianshi Zhou and David Graf and Lawler, \{Michael J.\} and Goddard, \{Paul A.\} and Louis Taillefer and Ramshaw, \{B. J.\}",

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doi = "10.1038/s41567-022-01514-1",

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AU - Fang, Yawen

AU - Grissonnanche, Gaël

AU - Legros, Anaëlle

AU - Verret, Simon

AU - Laliberté, Francis

AU - Collignon, Clément

AU - Ataei, Amirreza

AU - Dion, Maxime

AU - Zhou, Jianshi

AU - Graf, David

AU - Lawler, Michael J.

AU - Goddard, Paul A.

AU - Taillefer, Louis

AU - Ramshaw, B. J.

PY - 2022/5

Y1 - 2022/5

N2 - The nature of the pseudogap phase remains a major puzzle in our understanding of cuprate high-temperature superconductivity. Whether or not this metallic phase is defined by any of the reported broken symmetries, the topology of its Fermi surface remains a fundamental open question. Here we use angle-dependent magnetoresistance (ADMR) to measure the Fermi surface of the La1.6–xNd0.4SrxCuO4 cuprate. Outside the pseudogap phase, we fit the ADMR data and extract a Fermi surface geometry that is in excellent agreement with angle-resolved photoemission data. Within the pseudogap phase, the ADMR is qualitatively different, revealing a transformation of the Fermi surface. We can rule out changes in the quasiparticle lifetime as the sole cause of this transformation. We find that our data are most consistent with a pseudogap Fermi surface that consists of small, nodal hole pockets, thereby accounting for the drop in carrier density across the pseudogap transition found in several cuprates.

AB - The nature of the pseudogap phase remains a major puzzle in our understanding of cuprate high-temperature superconductivity. Whether or not this metallic phase is defined by any of the reported broken symmetries, the topology of its Fermi surface remains a fundamental open question. Here we use angle-dependent magnetoresistance (ADMR) to measure the Fermi surface of the La1.6–xNd0.4SrxCuO4 cuprate. Outside the pseudogap phase, we fit the ADMR data and extract a Fermi surface geometry that is in excellent agreement with angle-resolved photoemission data. Within the pseudogap phase, the ADMR is qualitatively different, revealing a transformation of the Fermi surface. We can rule out changes in the quasiparticle lifetime as the sole cause of this transformation. We find that our data are most consistent with a pseudogap Fermi surface that consists of small, nodal hole pockets, thereby accounting for the drop in carrier density across the pseudogap transition found in several cuprates.

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VL - 18

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EP - 564

JO - Nature Physics

JF - Nature Physics

IS - 5

ER -

Fermi surface transformation at the pseudogap critical point of a cuprate superconductor

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