High density of states in the pseudogap phase of the cuprate superconductor HgBa2CuO4 + δ

Abstract

The specific heat C of the single-layer cuprate superconductor HgBa2CuO4 + δ was measured in an underdoped crystal with T c = 72 K at temperatures down to 2 K in magnetic fields up to 35 T, a field large enough to suppress superconductivity at that doping (p 0.09). In the normal state at H = 35 T, a residual linear term of magnitude γ = 12 2 mJ/K2mol is observed in C/T as T 0, a direct measure of the electronic density of states. This high value of γ has two major implications. First, it is significantly larger than the value measured in overdoped cuprates outside the pseudogap phase (p >p), such as La2-xSrxCuO4 and Tl2Ba2CuO6 + δ at p 0.3, where γ 7 mJ/K2mol. Given that the pseudogap causes a loss of density of states, and assuming that HgBa2CuO4 + δ has the same γ value as other cuprates at p 0.3, this implies that γ in HgBa2CuO4 + δ must peak between p 0.09 and p 0.3, namely at (or near) the critical doping p where the pseudogap phase is expected to end (p 0.2). Secondly, the high γ value implies that the Fermi surface must consist of more than the single electron-like pocket detected by quantum oscillations in HgBa2CuO4 + δ at p 0.09, whose effective mass m= 2.7× m0 yields only γ = 4.0 mJ/K2mol. This missing mass imposes a revision of the current scenario for how pseudogap and charge order respectively transform and reconstruct the Fermi surface of cuprates.