Abstract
We measured the reflectivity of the multifold semimetal RhSi in a frequency range from 80 to 20000 cm$^{-1}$ (10 meV - 2.5 eV) at temperatures down to 10 K. The optical conductivity, calculated from the reflectivity, is dominated by the free-carrier (Drude) contribution below 1000 cm$^{-1}$ (120 meV) and by interband transitions at higher frequencies. The temperature-induced changes in the spectra are generally weak: only the Drude bands narrow upon cooling, with an unscreened plasma frequency that is constant with temperature at approximately 1.4 eV, in agreement with a weak temperature dependence of the free-carrier concentration determined by Hall measurements. The interband portion of conductivity exhibits two linear-in-frequency regions below 5000 cm$^{-1}$ ($\sim$ 600 meV), a broad flat maximum at around 6000 cm$^{-1}$ (750 meV), and a further increase starting around 10000 cm$^{-1}$ ($\sim$ 1.2 eV). We assign the linear behavior of the interband conductivity to transitions between the linear bands near the band crossing points. Our findings are in accord with the predictions for the low-energy conductivity behavior in multifold semimetals and with earlier computations based on band structure calculations for RhSi.
Highlights
Multifold fermions are quasiparticles described by higherspin generalizations of the Weyl equation
Infrared-active phonons and electronic transitions are revealed in this study
The interband optical conductivity demonstrates a linear increase at low frequencies
Summary
Multifold fermions are quasiparticles described by higherspin generalizations of the Weyl equation. A number of such semimetals were recently predicted and experimentally confirmed among the materials from the space group 198 (SG198), whose symmetry is noncentrosymmetric and has no mirror planes, leading to a realization of “topological chiral crystals” [3,4,5,6,7,8,9]. In such semimetals, the quantized circular photogalvanic effect (QCPGE) was forecasted in 2017 [10].
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