Superconducting Electrometer Based on the Resistively Shunted Bloch Transistor

TL;DR

This paper presents a superconducting electrometer based on a resistively shunted Bloch transistor with on-chip Cr resistor, demonstrating gate modulation and operation in high-damping, high-noise conditions.

Contribution

It introduces a novel superconducting electrometer design using a resistively shunted Bloch transistor with interferometer loops, operating effectively in high-damping, noisy environments.

Findings

No hysteresis observed in I-V curves.

Gate modulation with a period of e achieved.

Critical current aligns with electromagnetic environment theory.

Abstract

We have fabricated the Bloch transistor shunted on-chip by a small-sized Cr resistor with Rs about 1 kOhm. The Bloch transistor normally consists of two small Josephson junctions connected in series, which in our case have been replaced by two superconducting interferometer loops, each with two junctions in parallel. A capacitively coupled gate is supplied to control the induced charge of the small intermediate electrode (island) of the transistor. The measured I-V curves show no hysteresis and correspond to the operation of a effective Josephson junction at the high-damping and strong-noise limits. The critical current of the system was found to be close to its nominal value, that is in accordance with the electromagnetic environment theory. The I-V curves were modulated by the gate with a period of e and a maximum swing of about 2 /mu_V. Such rather moderate modulation results from the Josephson-to- charging energies ratio, Ej/Ec about 9, in our sample being far from its optimum value of 0.3 up to 1.