Spontaneous decay of artificial atoms in a multi-qubit system

We consider a one-dimensional chain of N equidistantly spaced noninteracting qubits embedded in an open waveguide. In the frame of single-excitation subspace, we systematically study the evolution of qubits' amplitudes if the only qubit in the chain was initially excited. We show that the tempo...

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Bibliographic Details
Published in:Low temperature physics (Woodbury, N.Y.) N.Y.), 2021-10, Vol.47 (10), p.834-842
Main Authors: Greenberg, Ya. S., Shtygashev, A. A., Moiseev, A. G.
Format: Article
Language:English
Subjects:
Amplitudes
Chains
Damping
Excitation
Oscillations
Photon emission
Photons
Quantum dots
Waveguides
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Summary:We consider a one-dimensional chain of N equidistantly spaced noninteracting qubits embedded in an open waveguide. In the frame of single-excitation subspace, we systematically study the evolution of qubits' amplitudes if the only qubit in the chain was initially excited. We show that the temporal dynamics of qubits' amplitudes crucially depend on the value of kd, where k is the wave vector, d is a distance between neighbor qubits. If kd is equal to an integer multiple of π, then the qubits are excited to a stationary level which scales as N−1. We show that in this case, it is the dark states which prevent qubits from decaying to zero even though they do not contribute to the output spectrum of photon emission. For other values of kd the excitations of qubits have the form of damping oscillations, which represent the vacuum Rabi oscillations in a multi-qubit system. In this case, the output spectrum of photon radiation is defined by a subradiant state with the smallest width.
ISSN:1063-777X
1090-6517
DOI:10.1063/10.0006063