Abstract

Quantum computers hold the potential to solve key tasks exponentially faster than classical computers, giving rise to a new quantum era. Classical transistor scaling achieved the integration of billions of transistors on-chip reaching sizes so small that a single electron or hole can be trapped and held in place. The spin of such a trapped charge is a prime contender for building scalable quantum bits out of classical transistors, thus making semiconductor spins a leading candidate for full-scale quantum computing.

The spin-orbit interaction (SOI) is at the heart of key phenomena in condensed matter physics. It arises from the relativistic physics conveniently creating magnetic out of electric fields, working very efficiently for holes in semiconductors. This makes possible all-electrical coherent spin manipulation without requiring micromagnets, thus reducing the qubit footprint and improving scaling. Yet the SOI , similar to micromagnets, also opens the door for charge noise to cause spin dephasing, thus posing a fundamental challenge for spin qubits.

In this talk, I will present recent progress on building spin-orbit qubits with holes in Ge/Si core/shell nanowires and Si fin FETs. Highlights include ultrafast qubits, taking only 1 ns to coherently rotate a spin from pointing up to down; operation of spin qubits up to 5 K, where vast cooling power becomes available, making possible integration of the classical control electronics; operation of a 2-qubit gate with highly anisotropic exchange, allowing for high fidelity gate operation while operating at high speeds; and finally a sweet spot combining both maximal coherence and maximal speed, thus opening new avenues for ultrafast and highly coherent spin-orbit qubits.

This work was supported by the NCCR SPIN , the Swiss National quantum computation program of the Swiss NSF , the Swiss Nanoscience Institute (SNI), the Georg H. Endress Foundation, and the EU H2020 European Microkelvin Platform EMP , TOPSQUAD, QUSTEC and QLSI programs.