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Graphene Enabled Low-Control Quantum Gates between Static and Mobile Spins

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arxiv 1307.0217 v1 pith:AW4F2EEN submitted 2013-06-30 quant-ph cond-mat.mes-hall

Graphene Enabled Low-Control Quantum Gates between Static and Mobile Spins

classification quant-ph cond-mat.mes-hall
keywords staticmobilequantumgatesgraphenecontrolelectronklein
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We show that the feature of Klein tunneling makes graphene a unique interface for implementing low control quantum gates between static and mobile qubits. A ballistic electron spin is considered as the mobile qubit, while the static qubit is the electronic spin of a quantum dot fixed in a graphene nanoribbon. Scattering is the low control mechanism of the gate, which, in other systems, is really difficult to exploit because of both back-scattering and the momentum dependence of scattering. We find that Klein tunneling enables the implementation of quasi-deterministic quantum gates regardless of the momenta or the shape of the wave function of the incident electron. The Dirac equation is used to describe the system in the one particle approximation with the interaction between the static and the mobile spins modelled by a Heisenberg Hamiltonian. Furthermore, we discuss an application of this model to generate entanglement between two well separated static qubits.

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