Electronic control and switching of entangled spin state using anisotropy and exchange in the three-particle paradigm
Abstract
We explore the control and switching of the entangled spin states of multi-spin particle qubit coupled to an electron using a three-particle spin model described by Si (i=1,2,3), in which S1=12 is an electron and S2,3 can have any spin with both exchange coupling and magnetic anisotropy. We derive a general formula for the existence of a switching (DJ) resonance for any spin S2,3. We further contrast the entanglement switching mechanisms for the S2,3=12 and S2,3=1 spin models. We find that while the onsite magnetic anisotropy in the case of S2,3>12 allows full control of their spin states via interaction with S1, in order to achieve acceptable control of a Bloch vector within the S2,3=12 model, additional mechanisms, such as anisotropic exchange coupling, are required.
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