A CMOS dynamic random access architecture for radio-frequency readout of quantum devices

Schaal, Simon and Rossi, Alessandro and Ciriano-Tejel, Virginia N. and Yang, Tsung-Yeh and Barraud, Sylvain and Morton, John J.L. and Gonzalez-Zalba, M. Fernando (2019) A CMOS dynamic random access architecture for radio-frequency readout of quantum devices. Nature Electronics, 2 (6). pp. 236-242. ISSN 2520-1131

[img] Text (Schaal-etal-NE-2019-A-CMOS-dynamic-random-access-architecture-for-radio-frequency)
Schaal_etal_NE_2019_A_CMOS_dynamic_random_access_architecture_for_radio_frequency.pdf
Accepted Author Manuscript
Restricted to Repository staff only until 17 December 2019.

Download (1MB) | Request a copy from the Strathclyde author

    Abstract

    As quantum processors become more complex, they will require efficient interfaces to deliver signals for control and readout while keeping the number of inputs manageable. Complementary metal–oxide–semiconductor (CMOS) electronics offers established solutions to signal routing and dynamic access, and the use of a CMOS platform for the qubits themselves offers the attractive proposition of integrating classical and quantum devices on-chip. Here, we report a CMOS dynamic random access architecture for readout of multiple quantum devices operating at millikelvin temperatures. Our circuit is divided into cells, each containing a control field-effect transistor and a quantum dot device, formed in the channel of a nanowire transistor. This set-up allows selective readout of the quantum dot and charge storage on the quantum dot gate, similar to one-transistor–one-capacitor (1T-1C) dynamic random access technology. We demonstrate dynamic readout of two cells by interfacing them with a single radio-frequency resonator. Our approach provides a path to reduce the number of input lines per qubit and allow large-scale device arrays to be addressed.