Abstract
Topological quantum states of matter, characterized by geometrical features of electronic band structures, have been extensively studied. Among them, the topological electronic state with magnetic order remains elusive because of a scarce number of examples. Here we present experimental observations proving that the pyrochlore iridate, when electronically tuned, can be a topological Weyl semimetal as predicted by recent theories. We observe a sizable spontaneous Hall conductivity with minimal magnetization only within a few Kelvin below the all-in all-out magnetic ordering temperature. Our theoretical calculation, which is quantitatively consistent with the observation, suggests that the presence of linearly-dispersing crossing points (Weyl points), acting as a source/sink of a quantized magnetic flux, potentially gives rise to such an enormous effect. The manifestation of the salient Hall response provides one important example of topological states, which promotes a better understanding of Weyl semimetal and indicates the new research direction for the topological-materials design.
Highlights
Topological quantum states of matter, characterized by geometrical features of electronic band structures, have been extensively studied
An intrinsic mechanism of anomalous Hall effect (AHE) was first proposed by Karplus and Luttinger who attributed it to the electronic band structure with spin–orbit interaction2, which generates an additional contribution in a Hall current with no energy consumption
The recent angle-resolved photoemission (ARPES) study has revealed that the ground state of the paramagnetic metal R = Pr is a unique semimetal with a quadratic-band-touching point right across the Fermi level, which evolves into abundant topologically-nontrivial phases by symmetry-breaking perturbations15,16
Summary
Topological quantum states of matter, characterized by geometrical features of electronic band structures, have been extensively studied. We exploit the electronic transport measurements on pyrochlore Nd2Ir2O7 and (Nd0.5Pr0.5)2Ir2O7 by applying pressure and magnetic field to search for the smoking gun of the predicted WSM state.
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