We report the design and implementation of a high-performance superconducting quantum interference proximity transistor (SQUIPT) based on aluminum-copper (Al-Cu) technology. With the adoption of a thin and short copper nanowire we demostrate full phase-driven modulation of the proximity-induced minigap in the normal metal density of states. Under optimal bias we record unprecedently high flux-to-voltage (up to 3 mV/Φ0) and flux-to-current (exceeding 100 nA/Φ0) transfer function values at sub-Kelvin temperatures, where Φ0 is the flux quantum. The best magnetic flux resolution (as low as 500 nΦ0/Hz at 240 mK, being limited by the room temperature pre-amplification stage) is reached under fixed current bias. These figures of merit combined with ultra-low power dissipation and micrometer-size dimensions make this mesoscopic interferometer attractive for low-temperature applications such as the investigation of the magnetization of small spin populations.
@article{arxiv.1404.4206,
title = {Highly-sensitive superconducting quantum interference proximity transistor},
author = {A. Ronzani and C. Altimiras and F. Giazotto},
journal= {arXiv preprint arXiv:1404.4206},
year = {2014}
}