Engineering dissipative channels for realizing Schrödinger cats in SQUIDs
Mark Everitt
T.P. Spiller
G.J. Milburn
Richard D. Wilson
Alexandre Zagoskin
2134/21296
https://repository.lboro.ac.uk/articles/journal_contribution/Engineering_dissipative_channels_for_realizing_Schr_dinger_cats_in_SQUIDs/9408791
We show that by engineering the interaction with the environment, there exists a large
class of systems that can evolve irreversibly to a cat state. To be precise, we show that it is possible to engineer an irreversible process so that the steady state is close to a pure Schrödinger’s cat state by using double well systems and an environment comprising two-photon (or phonon) absorbers.We also show that it should be possible to prolong the lifetime of a Schrödinger’s cat state exposed to the destructive effects of a conventional
single-photon decohering environment. In addition to our general analysis, we present a concrete circuit realization of both system and environment that should be fabricatable with current technologies. Our protocol should make it easier to prepare and maintain Schrödinger cat states, which would be useful in applications of quantum metrology and information processing as well as being of interest to those probing the quantum to classical transition.
2016-05-20 10:20:00
Cat state
Quantum metrology
Single-photon decoherence
Decoherence
Two-photon absorbers
Quantum to classical transition
Double well systems
Physical Sciences not elsewhere classified