npj Quantum Information (Oct 2023)

Electrical manipulation of a single electron spin in CMOS using a micromagnet and spin-valley coupling

  • Bernhard Klemt,
  • Victor Elhomsy,
  • Martin Nurizzo,
  • Pierre Hamonic,
  • Biel Martinez,
  • Bruna Cardoso Paz,
  • Cameron Spence,
  • Matthieu C. Dartiailh,
  • Baptiste Jadot,
  • Emmanuel Chanrion,
  • Vivien Thiney,
  • Renan Lethiecq,
  • Benoit Bertrand,
  • Heimanu Niebojewski,
  • Christopher Bäuerle,
  • Maud Vinet,
  • Yann-Michel Niquet,
  • Tristan Meunier,
  • Matias Urdampilleta

DOI
https://doi.org/10.1038/s41534-023-00776-8
Journal volume & issue
Vol. 9, no. 1
pp. 1 – 7

Abstract

Read online

Abstract For semiconductor spin qubits, complementary-metal-oxide-semiconductor (CMOS) technology is a promising candidate for reliable and scalable fabrication. Making the direct leap from academic fabrication to qubits fully fabricated by industrial CMOS standards is difficult without intermediate solutions. With a flexible back-end-of-line (BEOL), functionalities such as micromagnets or superconducting circuits can be added in a post-CMOS process to study the physics of these devices or achieve proofs-of-concept. Once the process is established, it can be incorporated in the foundry-compatible process flow. Here, we study a single electron spin qubit in a CMOS device with a micromagnet integrated in the flexible BEOL. We exploit the synthetic spin orbit coupling (SOC) to control the qubit via electric fields and we investigate the spin-valley physics in the presence of SOC where we show an enhancement of the Rabi frequency at the spin-valley hotspot. Finally, we probe the high frequency noise in the system using dynamical decoupling pulse sequences and demonstrate that charge noise dominates the qubit decoherence in this range.