Integrated Control Addressing Circuits for a Surface Code Quantum Computer in Silicon

Abstract

Quantum computers require a coordinated operation on a large number of quantum bits (qubits), presenting considerable obstacles such as system integration on a large scale, individual qubits control with precision, and significant error correction overhead. Silicon (Si) quantum dot (QD) spin qubits paired with CMOS control circuits promise a scalable solution due to its potential for large-scale integration utilizing well-established semiconductor technologies. This paper proposes a control addressing scheme for QD spin qubits operating on a node network architecture. Compared to the typical 2-dimensional array architecture, this approach considerably lowers the area constraint for control signal routing. Scalable circuits are designed to route the control signals for local and global operations of a surface code quantum error correction through the modular design of tiered switches controlled by demultiplexers. The proposed method is a critical step toward implementing scalable solid-state quantum processors.