TY - GEN
T1 - Virtual Noiseless Amplification
AU - Janousek, Jiri
AU - Chrzanowski, Helen
AU - Hosseini, Sarah
AU - Assad, Syed
AU - Symul, Thomas
AU - Walk, Nathan
AU - Ralph, Tim
AU - Lam, Ping Koy
PY - 2013
Y1 - 2013
N2 - The unavoidable addition of noise during amplification is a well known signature of quantum mechanics. It is at the heart of fundamental results such as the no-cloning theorem, quantum limited metrology, quantum key distribution and the impossibility of increasing entanglement by local operations. Nonetheless one can still avoid the unavoidable by moving to a non-deterministic protocol. This novel concept and a linear optics implementation have been proposed [1] and experimentally realised for the case of amplifying coherent states [2-4], qubits [5,6] and the concentration of phase information [7]. All these were extremely challenging experiments, with only [2] demonstrating entanglement distillation and none directly showing the EPR distillation necessary for application to CV QKD. Furthermore the success probability of these experiments was substantially worse than the theoretical considerations would imply. However as has been noted in [8,9] it is possible to virtually implement noiseless amplification (NLA) and hence entanglement distillation via post-selective measurements, achieving significant distillation with a much improved probability of success.
AB - The unavoidable addition of noise during amplification is a well known signature of quantum mechanics. It is at the heart of fundamental results such as the no-cloning theorem, quantum limited metrology, quantum key distribution and the impossibility of increasing entanglement by local operations. Nonetheless one can still avoid the unavoidable by moving to a non-deterministic protocol. This novel concept and a linear optics implementation have been proposed [1] and experimentally realised for the case of amplifying coherent states [2-4], qubits [5,6] and the concentration of phase information [7]. All these were extremely challenging experiments, with only [2] demonstrating entanglement distillation and none directly showing the EPR distillation necessary for application to CV QKD. Furthermore the success probability of these experiments was substantially worse than the theoretical considerations would imply. However as has been noted in [8,9] it is possible to virtually implement noiseless amplification (NLA) and hence entanglement distillation via post-selective measurements, achieving significant distillation with a much improved probability of success.
UR - http://www.scopus.com/inward/record.url?scp=84898736829&partnerID=8YFLogxK
M3 - Conference contribution
SN - 9781479905942
T3 - Optics InfoBase Conference Papers
BT - International Quantum Electronics Conference, IQEC 2013
T2 - International Quantum Electronics Conference, IQEC 2013
Y2 - 12 May 2013 through 16 May 2013
ER -