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Paper detail

Spin-wave gap collapse in Rh-doped Sr2IrO4

We use resonant inelastic x-ray scattering (RIXS) at the Ir L3 edge to study the effect of hole doping upon the Jeff=1/2 Mott-insulating state in Sr2IrO4, via Rh replacement of the Ir site. The spin-wave gap, associated with XY-type spin-exchange anisotropy, collapses with increasing Rh content, prior to the suppression of the Mott-insulating state and in contrast to electron doping via La substitution of the Sr site. At the same time, despite heavy damping, the d-d excitation spectra retain their overall amplitude and dispersion character. A careful study of the spin-wave spectrum reveals that deviations from the J1-J2-J3 Heisenberg used to model the pristine system disappear at intermediate doping levels. These findings are interpreted in terms of a modulation of Ir-Ir correlations due to the influence of Rh impurities upon nearby Ir wave functions, even as the single-band Jeff=1/2 model remains valid up to full carrier delocalization. They underline the importance of the transition metal site symmetry when doping pseudospin systems such as Sr2IrO4.

preprint2020arXivOpen access
J. BertinshawJ. K. KimJ. PorrasK. UedaN. H. SungA. EfimenkoA. BombardiJungho KimB. KeimerB. J. Kim
cond-mat.str-el
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J. BertinshawJ. K. KimJ. PorrasK. UedaN. H. SungA. EfimenkoA. BombardiJungho KimB. KeimerB. J. Kim

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