Abstract
Progress towards the realization of quantum computers requires persistent advances in their constituent building blocks – qubits. Novel qubit platforms that simultaneously embody long coherence, fast operation, high fidelity, and large scalability offer compelling advantages in the construction of quantum computers. Electrons, ubiquitous elementary particles of non-zero charge, spin and mass, have commonly been perceived as paradigmatic local quantum information carriers. Despite superior controllability and configurability, their practical performance as qubits through either motional or spin states depends critically on their material environment. In this talk, I will present our experimental realization of a new qubit platform based upon isolated single electrons trapped on an ultraclean solid neon surface in vacuum. By integrating an electron trap in a superconducting quantum circuit, we achieve strong coupling between the motional states of a single electron and a single microwave photon in an on-chip resonator [1]. Qubit gate operations and dispersive readout are successfully implemented. The measured relaxation time T1 and coherence time T2 are both on the order of 0.1 milliseconds. [2]. The single-shot readout fidelity is 98.1% and single-qubit gate fidelity is 99.97%. Simultaneous strong coupling of two qubits with a microwave resonator is also demonstrated, as a first step toward two-qubit entangling gates for universal quantum computing. These results show that electron-on-solid-neon (eNe) qubits outperform all existing charge qubits to date and rival state-of-the-art superconducting transmon qubits, offering an ideal platform for scalable quantum computing.
References:
[1] X. Zhou … and D. Jin, “Single electrons on solid neon as a solid-state qubit platform”, Nature 605, 46–50 (2022).
[2] X. Zhou … and D. Jin, “Electron charge qubits on solid neon with 0.1 millisecond coherence time”, arXiv:2210.12337 (2022).