Pairing at a single Van Hove point

Risto Ojajärvi; Andrey V. Chubukov; Yueh Chen Lee; Markus Garst; Jörg Schmalian

doi:10.1038/s41535-024-00717-4

Pairing at a single Van Hove point

Risto Ojajärvi
, Andrey V. Chubukov
, Yueh Chen Lee
, Markus Garst
, Jörg Schmalian

Physics and Astronomy (Twin Cities)

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

8 Scopus citations

Abstract

We show that an interacting electronic system with a single ordinary or extended Van Hove point, which crosses the Fermi energy, is unstable against triplet superconductivity. The pairing mechanism is unconventional. There is no Cooper instability. Instead, pairing is due to the divergence of the density of states at a Van Hove point, leading to a superconducting quantum critical point at a finite detuning from the Van Hove point. The transition temperature is universally determined by the exponent governing the divergence of the density of states. Enhancing this exponent drastically increases T_c. The Cooper pair wave function has a non-monotonic momentum dependence with a steep slope near the gap nodes. In the absence of spin–orbit coupling, pairing fluctuations suppress a 2e spin-triplet state, but allow pairs of triplets to condense into a charge-4e singlet state at a temperature of similar order as our result.

Original language	English (US)
Article number	105
Journal	npj Quantum Materials
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41535-024-00717-4
State	Published - Dec 2024

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© The Author(s) 2024.

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abstract = "We show that an interacting electronic system with a single ordinary or extended Van Hove point, which crosses the Fermi energy, is unstable against triplet superconductivity. The pairing mechanism is unconventional. There is no Cooper instability. Instead, pairing is due to the divergence of the density of states at a Van Hove point, leading to a superconducting quantum critical point at a finite detuning from the Van Hove point. The transition temperature is universally determined by the exponent governing the divergence of the density of states. Enhancing this exponent drastically increases Tc. The Cooper pair wave function has a non-monotonic momentum dependence with a steep slope near the gap nodes. In the absence of spin–orbit coupling, pairing fluctuations suppress a 2e spin-triplet state, but allow pairs of triplets to condense into a charge-4e singlet state at a temperature of similar order as our result.",

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AU - Ojajärvi, Risto

AU - Chubukov, Andrey V.

AU - Lee, Yueh Chen

AU - Garst, Markus

AU - Schmalian, Jörg

PY - 2024/12

Y1 - 2024/12

N2 - We show that an interacting electronic system with a single ordinary or extended Van Hove point, which crosses the Fermi energy, is unstable against triplet superconductivity. The pairing mechanism is unconventional. There is no Cooper instability. Instead, pairing is due to the divergence of the density of states at a Van Hove point, leading to a superconducting quantum critical point at a finite detuning from the Van Hove point. The transition temperature is universally determined by the exponent governing the divergence of the density of states. Enhancing this exponent drastically increases Tc. The Cooper pair wave function has a non-monotonic momentum dependence with a steep slope near the gap nodes. In the absence of spin–orbit coupling, pairing fluctuations suppress a 2e spin-triplet state, but allow pairs of triplets to condense into a charge-4e singlet state at a temperature of similar order as our result.

AB - We show that an interacting electronic system with a single ordinary or extended Van Hove point, which crosses the Fermi energy, is unstable against triplet superconductivity. The pairing mechanism is unconventional. There is no Cooper instability. Instead, pairing is due to the divergence of the density of states at a Van Hove point, leading to a superconducting quantum critical point at a finite detuning from the Van Hove point. The transition temperature is universally determined by the exponent governing the divergence of the density of states. Enhancing this exponent drastically increases Tc. The Cooper pair wave function has a non-monotonic momentum dependence with a steep slope near the gap nodes. In the absence of spin–orbit coupling, pairing fluctuations suppress a 2e spin-triplet state, but allow pairs of triplets to condense into a charge-4e singlet state at a temperature of similar order as our result.

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ER -

Pairing at a single Van Hove point

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