Abstract
The thermal conductivity $\kappa$ of the cuprate superconductor La$_{1.6-x}$Nd$_{0.4}$Sr$_x$CuO$_4$ was measured down to 50 mK in seven crystals with doping from $p=0.12$ to $p=0.24$, both in the superconducting state and in the magnetic field-induced normal state. We obtain the electronic residual linear term $\kappa_0/T$ as $T \to 0$ across the pseudogap critical point $p^{\star}= 0.23$. In the normal state, we observe an abrupt drop in $\kappa_0/T$ upon crossing below $p^{\star}$, consistent with a drop in carrier density $n$ from $1 + p$ to $p$, the signature of the pseudogap phase inferred from the Hall coefficient. A similar drop in $\kappa_0/T$ is observed at $H=0$, showing that the pseudogap critical point and its signatures are unaffected by the magnetic field. In the normal state, the Wiedemann-Franz law, $\kappa_0/T=L_0/\rho(0)$, is obeyed at all dopings, including at the critical point where the electrical resistivity $\rho(T)$ is $T$-linear down to $T \to 0$. We conclude that the non-superconducting ground state of the pseudogap phase at $T=0$ is a metal whose fermionic excitations carry heat and charge as conventional electrons do.
Highlights
Cuprate high-temperature superconductors exhibit a variety of correlated phases that interact with each other and with superconductivity, and understanding their associated complex phase diagram is a central challenge of condensed matter physics [1]
We observe an abrupt drop in κ0=T upon crossing below p⋆, consistent with a drop in carrier density n from 1 þ p to p, the signature of the pseudogap phase inferred from the Hall coefficient
The phonon conductivity κph of cuprate superconductors goes as κph=T ∼ Tα [25], with α 1⁄4 1 at high doping where the system is a good metal and phonons are mainly scattered by electrons, as in overdoped Tl2201 [26]
Summary
Cuprate high-temperature superconductors exhibit a variety of correlated phases that interact with each other and with superconductivity, and understanding their associated complex phase diagram is a central challenge of condensed matter physics [1]. The chief mystery is the pseudogap phase [2,3], a phase that appears to break a number of symmetries, such as time reversal [4,5] and fourfold rotation [6,7], below a temperature T⋆, but whose fundamental nature is still unclear. At p⋆, the electrical resistivity remains T linear as T → 0 [9,10] (Fig. 1).
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
