The novel metallic states of the cuprates: Fermi liquids with topological order, and strange metals

TL;DR

This paper reviews the metallic states of hole-doped cuprates, exploring topological order, Fermi surface changes, and the strange metal phase through theoretical frameworks like TQFTs, Higgs phases, and critical theories.

Contribution

It introduces a unified theoretical approach linking topological quantum field theories, Fermi surface reconstruction, and Higgs criticality to explain cuprate metallic states and the pseudogap phase.

Findings

Compatibility of Z2 spin liquid TQFT with momentum balance

Construction of topological Fermi liquid states (FL* and ACL)

Description of pseudogap metal as Higgs phases with Ising-nematic order

Abstract

This article is based on a talk by S.S. at the Nambu Memorial Symposium at the University of Chicago. We review ideas on the nature of the metallic states of the hole-doped cuprate high temperature superconductors, with an emphasis on the connections between the Luttinger theorem for the size of the Fermi surface, topological quantum field theories (TQFTs), and critical theories involving changes in the size of the Fermi surface. We begin with the derivation of the Luttinger theorem for a Fermi liquid, using momentum balance during a process of flux-insertion in a lattice electronic model with toroidal boundary conditions. We then review the TQFT of the Z2 spin liquid, and demonstrate its compatibility with the toroidal momentum balance argument. This discussion leads naturally to a simple construction of `topological' Fermi liquid states: the fractionalized Fermi liquid (FL*) and the algebraic charge liquid (ACL). We present arguments for a description of the pseudogap metal of the cuprates using Z2-FL* or Z2-ACL states with Ising-nematic order. These pseudogap metal states are also described as Higgs phases of a SU(2) gauge theory. The Higgs field represents local antiferromagnetism, but the Higgs-condensed phase does not have long-range antiferromagnetic order: the magnitude of the Higgs field determines the pseudogap, the reconstruction of the Fermi surface, and the Ising-nematic order. Finally, we discuss the route to the large Fermi surface Fermi liquid via the critical point where the Higgs condensate and Ising nematic order vanish, and the application of Higgs criticality to the strange metal.