Hydrostatic-pressure effects on the pseudogap in slightly doped YBa2Cu3O7−δ single crystals

Abstract

The influence of hydrostatic pressure P up to 1.05GPa on resistivity ρ, excess conductivity σ′(T) and pseudogap Δ⁎(T) is investigated in slightly doped single crystals of YBa2Cu3O7−δ (Tc(P=0)≈49.2K and δ≈0.5). The critical temperature Tc is found to increase with increasing pressure at a rate dTc/dP=+5.1KGPa−1, while ρ(300K) decreases at a rate dlnρ/dP=(−19±0.2)%GPa−1. Near Tc, independently on pressure, σ′(T) is well described by the Aslamasov–Larkin and Hikami–Larkin fluctuation theories, demonstrating a 3D–2D crossover with increase of temperature. The crossover temperature T0 determines the coherence length along the c-axis ξc(0)≃(3.43±0.01)A˚ at P=0, which is found to decrease with increasing P. At the same time, Δ⁎ and the BCS ratio 2Δ⁎/kBTc both increase with increasing hydrostatic pressure at a rate dlnΔ⁎/dP≈0.36GPa−1, implying an increase of the coupling strength with increasing P. At low temperatures below Tpair, the shape of the Δ⁎(T) curve is found to be almost independent of pressure. At high temperatures, the shape of the Δ⁎(T) curve changes noticeably with increasing P, suggesting a strong influence of pressure on the lattice dynamics. This unusual behavior is observed for the first time.