Abstract
The coupling between lattice vibration quanta and valence electrons can induce charge density modulations and decisively influence the transport properties of materials, e.g. leading to conventional superconductivity. In high critical temperature superconductors, where electronic correlation is the main actor, the actual role of electron-phonon coupling (EPC) is being intensely debated theoretically and investigated experimentally. We present an in-depth study of how the EPC strength can be obtained directly from resonant inelastic x-ray scattering (RIXS) data through the theoretical approach derived by Ament et al. [EPL 95, 27008 (2011)]. The role of the model parameters (e.g. phonon energy $\omega_0$, intermediate state lifetime $1/\Gamma$, EPC matrix element $M$, and detuning energy $\Omega$) is thoroughly analyzed, providing general relations among them that can be used to make quantitative estimates of the dimensionless EPC $g = (M/\omega_0)^2$ without detailed microscopic modeling. We then apply these methods to very high resolution Cu $L_3$ edge RIXS spectra of three Nd$_{1+x}$Ba$_{2-x}$Cu$_3$O$_{7-\delta}$ films. For the insulating antiferromagnetic parent compound the value of $M$ as a function of the in-plane momentum transfer is obtained for Cu-O bond-stretching (breathing) and bond-bending (buckling) phonon branches. For the underdoped and the nearly optimally doped samples, the effects of Coulomb screening and of charge-density-wave correlations on $M$ are assessed. In light of the anticipated further improvements of the RIXS experimental resolution, this work provides a solid framework for an exhaustive investigation of the EPC in cuprates and other quantum materials.
Highlights
The role of the electron-phonon coupling (EPC) in the high-critical-temperature superconducting cuprates is still an open problem deserving further research
We present an in-depth study of how the EPC strength can be obtained directly from resonant inelastic x-ray scattering (RIXS) data through the theoretical approach derived by Ament et al [Europhys
We investigated three NBCO samples: (i) NBCO-AF: the sample is antiferromagnetic with x ≈ 0, δ ≈ 0.9, and with a Cu-O-Cu buckling angle of 6.35◦ [60,61]. (ii) NBCO-UD: the sample is underdoped with Tc = 63 K, hole doping of 0.11, x ≈ 0.2, δ ≈ 0, and a buckling angle of 6.74◦ [62]. (iii) NBCO-OP: the sample is very close to optimal doping with Tc = 90 K, x ≈ 0, δ ≈ 0, and a buckling angle of 7.75◦ [60]
Summary
The role of the electron-phonon coupling (EPC) in the high-critical-temperature (high-Tc) superconducting cuprates is still an open problem deserving further research. Even if pairing is not of the phonon-mediated BCS type [1], the question of a potential role for the EPC remains extremely interesting It has been suggested theoretically [2,3,4,5,6,7] that a synergy between a suitable phonon and other pair-driving excitations can greatly enhance the critical temperature Tc. In particular, in the case of magnetic excitations, even a small amount of EPC (per se irrelevant) should be sufficient to considerably increase Tc [7]. These examples, including results from the recent literature, provide new clues toward understanding the role of the EPC in the cuprates, on top of the long debated polaronic behavior of carriers in this class of materials [20,21,22,23]
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