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An Exchange-Coupled Donor Molecule in Silicon

Donors in silicon, conceptually described as hydrogen atom analogues in a semiconductor environment, have become a key ingredient of many "More-than-Moore" proposals such as quantum information processing [1-5] and single-dopant electronics [6, 7]. The level of maturity this field has reached has enabled the fabrication and demonstration of transistors that base their functionality on a single impurity atom [8, 9] allowing the predicted single-donor energy spectrum to be checked by an electrical transport measurement. Generalizing the concept, a donor pair may behave as a hydrogen molecule analogue. However, the molecular quantum mechanical solution only takes us so far and a detailed understanding of the electronic structure of these molecular systems is a challenge to be overcome. Here we present a combined experimental-theoretical demonstration of the energy spectrum of a strongly interacting donor pair in the channel of a silicon nanotransistor and show the first observation of measurable two-donor exchange coupling. Moreover, the analysis of the three charge states of the pair shows evidence of a simultaneous enhancement of the binding and charging energies with respect to the single donor spectrum. The measured data are accurately matched by results obtained in an effective mass theory incorporating the Bloch states multiplicity in Si, a central cell corrected donor potential and a full configuration interaction treatment of the 2-electron spectrum. Our data describe the basic 2-qubit entanglement element in Kane's quantum processing scheme [1], namely exchange coupling, implemented here in the range of molecular hybridization.