Nb nano superconducting quantum interference devices with high spin sensitivity for operation in magnetic fields up to 0.5\,T

Abstract

We investigate electric transport and noise properties of microstrip-type submicron direct current superconducting quantum interference devices (dc SQUIDs) based on Nb thin films and overdamped Josephson junctions with a HfTi barrier. The SQUIDs were designed for optimal spin sensitivity Sμ1/2 upon operation in intermediate magnetic fields B (tens of mT), applied perpendicular to the substrate plane. Our so far best SQUID can be continuously operated in fields up to B≈50\,mT with rms flux noise S, w1/2≤250\,n0/Hz1/2 in the white noise regime and spin sensitivity Sμ1/2≤29\,μB/Hz1/2. Furthermore, we demonstrate operation in B=0.5\,T with high sensitivity in flux S, w1/2≈680\,n0/Hz1/2 and in electron spin Sμ1/2≈79\,μB/Hz1/2. We discuss strategies to further improve the nanoSQUID performance.