6533b7d6fe1ef96bd1265bfe
RESEARCH PRODUCT
Removing phase ambiguity in fiber-based interferometers for coherent time-bin operations
Yu ZhangMichael KuesBennet FischerPiotr RoztockiStefania SciaraDavid J. MossChristian ReimerMehedi IslamRoberto Morandottisubject
Superposition principleInterferometryQuantum stateComputer scienceQubitQuantum channelQuantum entanglementQuantum informationTopologyInterference (wave propagation)description
Time is a practical and robust degree of freedom for the encoding of quantum information. Qubits encoded in so-called 'time-bins', allowing a discrete superposition of two potential arrival times, have their entanglement preserved even over long propagation distances in standard fiber networks [1]. Time has also been used for the preparation of more complex quantum systems, such as hyper-entangled and cluster states [2]. These qualities put time-bin encoding at the center of applications ranging from quantum state preparation through to quantum communications and information processing. One of the hallmarks of the scheme is that a nonlinear element has to be pumped with phase-coherent double-pulses, which can be achieved by using unbalanced interferometers [1], making their phase stability the key determinant of both state generation and analysis accuracy. However, the phase ambiguity arising from the periodicity of feedback signals [3], as well as the difficulty of stabilizing on interference maxima/minima, leave progress to be made in fiberbased interferometry for time-bin encodings.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-06-01 |