Nematic fluctuations in the non-superconducting iron pnictide BaFe$_{1.9-x}$Ni$_{0.1}$Cr$_{x}$As$_{2}$

TL;DR

This study investigates nematic fluctuations in a non-superconducting iron pnictide, revealing that spin and orbital degrees of freedom influence nematicity differently and are linked to transport and spin dynamics.

Contribution

It provides a comprehensive analysis of nematic fluctuations using transport, ARPES, and neutron scattering, highlighting the interplay between spins, orbitals, and charge carriers in iron pnictides.

Findings

Resistivity anisotropy depends on Cr doping and charge carrier type.

Different onset temperatures of spin excitation anisotropy suggest distinct energy scales of spin nematicity.

Orbital anisotropy onset near structural transition temperature is weak for studied compositions.

Abstract

The main driven force of the electronic nematic phase in iron-based superconductors is still under debate. Here, we report a comprehensive study on the nematic fluctuations in a non-superconducting iron pnictide system BaFe$_{1.9-x}$Ni$_{0.1}$Cr$_{x}$As$_{2}$ by electronic transport, angle-resolved photoemission spectroscopy (ARPES) and inelastic neutron scattering (INS) measurements. Previous neutron diffraction and transport measurements suggested that the collinear antiferromagnetism persists to $x=0.8$, with similar N\'{e}el temperature $T_N$ and structural transition temperature $T_s$ around 32 K, but the charge carriers change from electron type to hole type around $x=$ 0.5. In this study, we have found that the in-plane resistivity anisotropy also highly depends on the Cr dopings and the type of charge carriers. While ARPES measurements suggest possibly weak orbital anisotropy onset near $T_s$ for both $x=0.05$ and $x=0.5$ compounds, INS experiments reveal clearly different onset temperatures of low-energy spin excitation anisotropy, which is likely related to the energy scale of spin nematicity. These results suggest that the interplay between the local spins on Fe atoms and the itinerant electrons on Fermi surfaces is crucial to the nematic fluctuations of iron pnictides, where the orbital degree of freedom may behave differently from the spin degree of freedom, and the transport properties are intimately related to the spin dynamics.