Experimental demonstration of universal qudit control on a cavity oscillator via compiled Jaynes-Cummings gates with a transmon ancilla, reaching 96% mean post-selected process fidelity for qutrit gates.
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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.
Magnetic domain walls are positioned as a platform for scalable quantum computation architectures leveraging their quantum effects and mobility.
citing papers explorer
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Universal Jaynes-Cummings Control of an Oscillator
Experimental demonstration of universal qudit control on a cavity oscillator via compiled Jaynes-Cummings gates with a transmon ancilla, reaching 96% mean post-selected process fidelity for qutrit gates.
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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.
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Perspective: Quantum Computing on Magnetic Racetrack
Magnetic domain walls are positioned as a platform for scalable quantum computation architectures leveraging their quantum effects and mobility.