Integrated Circuits for Qubit Control in Trapped-Ion Quantum Computers

Trapped ions (TI) are one of the leading platforms for realizing a universal quantum computer (QC). They feature several advantages compared to competing technologies based on superconducting-, semiconductor- and other qubit technology platforms.

This work presents a from-scratch design of two integrated system-on-chip (SoC) microwave generator solutions for the implementation of single and two-qubit gates and functionality for partial state preparation, and readout. First, the working principle of a TI QC system is described, which is the basis for deducing the system requirements of an integrated SoC solution. Two different system architectures are analyzed in depth and compared against each other, as well as the conventional RT-based controller. Hereafter, the implementation of the systemblocks in a SiGe 130 nmBiCMOS process are outlined.

Measurements of both microwave generator systems are presented and put in relation to the aforementioned system requirements. The work concludes with the application validation of the microwave generator performing state control of up to four TI-based qubits. Performance metrics such as gate time and fidelity are extracted and compared to the current state-of-the-art RT-based microwave generator and competing QC system realizations.

The proposed microwave generator system achieves identical performance as its RT-based counterpart in terms of qubit state manipulation and comparable performance in terms of gate fidelity. Yet it requires two orders of magnitude less power and seven orders of magnitude less volume. To the best of the author’s knowledge, this is the first demonstration of an integrated circuit solution for TI based qubit state manipulation.