Negative exchange interaction in Si quantum dot arrays via valley-phase induced Z2 gauge field

Abstract

The exchange interaction J offers a powerful tool for quantum computation based on semiconductor spin qubits. However, the exchange interaction in two-electron systems in the absence of a magnetic field is usually constrained to be non-negative J ≥ 0, which inhibits the construction of various dynamically corrected exchange-based gates. In this work, we show that negative exchange J < 0 can be realized in two-electron Si quantum dot arrays in the absence of a magnetic field due to the presence of the valley degree of freedom. Here, valley phase differences between dots produce a non-trivial Z2 gauge field in the low-energy effective theory, which in turn can lead to a negative exchange interaction. In addition, we show that this Z2 gauge field can break Nagaoka ferromagnetism and be engineered by altering the occupancy of the dot array. Therefore, our work uncovers new tools for exchange-based quantum computing and a novel setting for studying quantum magnetism.

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