Coherent spin-exchange via a quantum mediator

TL;DR

This paper demonstrates a novel method for coherent long-distance spin interactions in quantum dot arrays using a quantum mediator, advancing quantum simulation and scalable quantum computing.

Contribution

It provides the first experimental demonstration of coherent spin-spin coupling via a quantum mediator in a quantum dot array.

Findings

Observed coherent time evolution of distant spins

Measured exchange frequency dependence on detuning

Showed potential for scalable spin qubit circuits

Abstract

Coherent interactions at a distance provide a powerful tool for quantum simulation and computation. The most common approach to realize an effective long-distance coupling 'on-chip' is to use a quantum mediator, as has been demonstrated for superconducting qubits and trapped ions. For quantum dot arrays, which combine a high degree of tunability with extremely long coherence times, the experimental demonstration of coherent spin-spin coupling via an intermediary system remains an important outstanding goal. Here, we use a linear triple-quantum-dot array to demonstrate a first working example of a coherent interaction between two distant spins via a quantum mediator. The two outer dots are occupied with a single electron spin each and the spins experience a superexchange interaction through the empty middle dot which acts as mediator. Using single-shot spin read-out we measure the coherent time evolution of the spin states on the outer dots and observe a characteristic dependence of the exchange frequency as a function of the detuning between the middle and outer dots. This approach may provide a new route for scaling up spin qubit circuits using quantum dots and aid in the simulation of materials and molecules with non-nearest neighbour couplings such as MnO, high-temperature superconductors and DNA. The same superexchange concept can also be applied in cold atom experiments.