Spin torque from inhomogeneous current produces periodic magnonic frequency modulation in a bicomponent nanopatterned crystal, resulting in avoided crossings and tunable hybrid modes between localized and propagating Damon-Eshbach waves.
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Non-reciprocal and chiral magnons mediate dissipative coupling of spin qubits to achieve steady-state Bell state entanglement in a driven hybrid NV-YIG system.
citing papers explorer
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Spin torque driven mode hybridization and band engineering in nanopatterned magnonic crystals
Spin torque from inhomogeneous current produces periodic magnonic frequency modulation in a bicomponent nanopatterned crystal, resulting in avoided crossings and tunable hybrid modes between localized and propagating Damon-Eshbach waves.
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Steady-state entanglement of spin qubits mediated by non-reciprocal and chiral magnons
Non-reciprocal and chiral magnons mediate dissipative coupling of spin qubits to achieve steady-state Bell state entanglement in a driven hybrid NV-YIG system.