Abstract
Resonant optical excitation of apical oxygen vibrational modes in the normal state of underdoped YBa2Cu3O6+x induces a transient state with optical properties similar to those of the equilibrium superconducting state. Amongst these, a divergent imaginary conductivity and a plasma edge are transiently observed in the photo-stimulated state. Femtosecond hard x-ray diffraction experiments have been used in the past to identify the transient crystal structure in this non-equilibrium state. Here, we start from these crystallographic features and theoretically predict the corresponding electronic rearrangements that accompany these structural deformations. Using density functional theory, we predict enhanced hole-doping of the CuO2 planes. The empty chain Cu dy2-z2 orbital is calculated to strongly reduce in energy, which would increase c-axis transport and potentially enhance the interlayer Josephson coupling as observed in the THz-frequency response. From these results, we calculate changes in the soft x-ray absorption spectra at the Cu L-edge. Femtosecond x-ray pulses from a free electron laser are used to probe changes in absorption at two photon energies along this spectrum and provide data consistent with these predictions.
Highlights
Unconventional high-temperature superconductivity in the cuprates appears as holes are doped into the CuO2 planes of the parent compounds
We used density functional theory to calculate the electronic rearrangement driven by this lattice deformation
These calculations predicted an enhancement in hole doping of the CuO2 planes
Summary
Unconventional high-temperature superconductivity in the cuprates appears as holes are doped into the CuO2 planes of the parent compounds. The hole doping of these planes is controlled by the oxygen content of Cu-O chains, which form along the baxis in between the bilayers. The critical temperature can further be enhanced by the application of static pressure.. The critical temperature can further be enhanced by the application of static pressure.2–5 This effect has been attributed to an increase in hole doping as a result of additional electron transfer from the CuO2 planes to the Cu-O chains, driven by a reduction in the Cu(2)–O(4) distance.. The critical temperature of underdoped compounds under pressure can exceed that at optimal doping
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