First-order structural transition and pressure-induced lattice/phonon anomalies in Sr$_2$IrO$_4$

TL;DR

This study reveals a first-order structural phase transition and pressure-induced lattice/phonon anomalies in Sr$_2$IrO$_4$, providing insights into competing electronic states and potential implications for superconductivity under high pressure.

Contribution

The paper combines experimental and theoretical methods to identify multiple pressure-induced phase transitions and lattice anomalies in Sr$_2$IrO$_4$, highlighting possible electronic instabilities and competing phases.

Findings

First-order phase transition with 8% c-axis collapse at high pressure.

Lattice and phonon anomalies indicating crossovers between competing states.

Emergence of symmetry-breaking lattice strain and phonon mode disappearance.

Abstract

We investigate the crystal structure and lattice vibrations of Sr$_2$IrO$_4$ by a combined phonon Raman scattering and x-ray powder diffraction experiment under pressures up to $66$ GPa and room temperature. Density functional theory (DFT) and $ab$-initio lattice dynamics calculations were also carried out. A first-order structural phase transition associated with an $8$ % collapse of the $c$-axis is observed at high pressures, with phase coexistence being observed between $\sim 40$ and $55$ GPa. At lower pressures, lattice and phonon anomalies were observed, reflecting crossovers between isostructural competing states. A critical pressure of $P_1=17$ GPa is associated with: (i) a reduction of lattice volume compressibility and a change of behavior of the tetragonal $c/a$ ratio take place above $P_1$; (ii) a four-fold symmetry-breaking lattice strain associated with lattice disorder; (iii) disappearance of two Raman active modes (at $\sim 180$ and $\sim 260$ cm$^{-1}$); and (iv) development of an asymmetric Fano lineshape for the $\sim 390$ cm$^{-1}$ mode. DFT indicates that the phase above $P_1$ is most likely non-magnetic. Exploring the similarities between iridate and cuprate physics, we argue that these observations are consistent with the emergence of a rotational symmetry-breaking electronic instability at $P_1$, providing hints for the avoided metallization under pressure and supporting the hypothesis of possible competing orders that are detrimental to superconductivity in this family. Alternative scenarios for the transition at $P_1$ are also suggested and critically discussed. Additional phonon and lattice anomalies in the tetragonal phase are observed at $P_2=30$ and $P_3=40$ GPa, indicating further competing phases that are stabilized at high pressures.