Gauge-gravity duality comes to the lab: evidence of momentum-dependent scaling exponents in the nodal electron self-energy of cuprate strange metals

TL;DR

This paper demonstrates that a holographic semi-holographic model with momentum-dependent scaling exponents can accurately describe the anomalous spectral functions observed in cuprate strange metals, linking theoretical models to experimental ARPES data.

Contribution

It introduces a semi-holographic model with momentum-dependent exponents that explains experimental spectral asymmetries in cuprate strange metals.

Findings

The model captures departure from Lorentzian line shapes in spectral functions.

It explains momentum-dependent asymmetries observed in ARPES measurements.

The model aligns with experimental data across various doping levels and temperatures.

Abstract

We show that the momentum-dependent scaling exponents of the holographic fermion self-energy of the conformal-to-AdS$_2$ Gubser-Rocha model can describe new findings from angle-resolved photoemission spectroscopy experiments on a single layer (Pb,Bi)$_{2}$Sr$_{2-x}$La$_x$CuO$_{6+\delta}$ copper-oxide. In particular, it was recently observed, in high-precision measurements on constant energy cuts along the nodal direction, that the spectral function departs from the Lorentzian line shape that is expected from the power-law-liquid model of a nodal self-energy, with an imaginary part featureless in momentum as $\Sigma''_{\text{PLL}}(\omega) \propto (\omega^2)^\alpha$. By direct comparison with experimental results, we provide evidence that this departure from either a Fermi liquid or the power-law liquid, resulting in an asymmetry of the spectral function as a function of momentum around the central peak, is captured at low temperature and all dopings by a semi-holographic model that predicts a momentum-dependent scaling exponent in the electron self-energy as $\Sigma(\omega,k) \propto \omega (-\omega^2)^{\alpha (1 - (k - k_F)/k_F) - 1/2}$, with $\hbar k_F$ the Fermi momentum.