Integration of buried nanomagnet and silicon spin qubits in a one-dimensional fin structure

Abstract

We adopt a buried nanomagnet (BNM) technology on a one-dimensional (1D) array of silicon spin qubits, and its availability was investigated using numerical simulations. The qubit array is formed in the center of the Si fin and the nanomagnet is buried in the lower lateral part of the qubits. The nanomagnet placed near the qubit generates a strong slanting magnetic field in the qubit, enabling X-gate operation approximately 15 times faster than in conventional cases. Furthermore, the formation of a BNM using a self-aligned process suppresses the dimensional variation of the nanomagnet caused by process variation, thereby mitigating the slanting field fluctuation and fidelity degradation. In addition, even for multiple qubits formed in the Si fin, the BNM with excess length generated a uniform slanting field, mitigating fidelity degradation and enabling all qubits to operate using a single-frequency microwave. Therefore, the proposed structure is useful for 1D integrated structures.