Electric coupling in scanning SQUID measurements

Abstract

Scanning SQUID is a local magnetometer which can image flux through its pickup loop due to DC magnetic fields (). Scanning SQUID can also measure a sample's magnetic response to an applied current (d/dI) or voltage (d/dV) using standard lock-in techniques. In this manuscript, we demonstrate that electric coupling between the scanning SQUID and a back gate-tuned, magnetic sample can lead to a gate-voltage dependent artifact when imaging d/dI or d/dV. The electric coupling artifact results in d/dV and d/dI images which mimic the spatial variation of the static magnetic fields from the sample (e.g. ferromagnetic domains). In back-gated EuS/Bi2Se3 bilayers, we show that the electric coupling effect is important, and is responsible for the reported signal from chiral currents in Y.H. Wang, et al. (DOI: 10.1126/science.aaa0508). Previous scanning SQUID current imaging experiments are unaffected by this artifact, as they are either on non-magnetic samples or the spatial distribution of magnetism does not match the features observed in d/dI. In conclusion, d/dI or d/dV imaging of magnetic, back-gated samples should only be applied and interpreted with great caution.