Specifically, for each connecting mode we impose the sideband condition∆(n) 0 +kωd1+lωd2 = ∆(n) with∆ (n) the residual engineered detuning that remains after sideband selection

Sideband selection with residual engineered detunings To activate the desired couplings to the two connecting modes while retaining residual engineered detunings, the drive frequen

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Loss-induced quantum nonreciprocity and entanglement in superconducting qubits

quant-ph · 2026-05-12 · unverdicted · novelty 5.0

Loss-induced phases in auxiliary cavities create asymmetric interference, yielding tunable nonreciprocal couplings and entanglement between remote transmon qubits.

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Loss-induced quantum nonreciprocity and entanglement in superconducting qubits quant-ph · 2026-05-12 · unverdicted · none · ref 6
Loss-induced phases in auxiliary cavities create asymmetric interference, yielding tunable nonreciprocal couplings and entanglement between remote transmon qubits.

Specifically, for each connecting mode we impose the sideband condition∆(n) 0 +kωd1+lωd2 = ∆(n) with∆ (n) the residual engineered detuning that remains after sideband selection

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