7 research outputs found
Parity effect and single-electron injection for Josephson-junction chains deep in the insulating state
We have made a systematic investigation of charge transport in 1D chains of
Josephson junctions where the characteristic Josephson energy is much less than
the single-island Cooper-pair charging energy, . Such
chains are deep in the insulating state, where superconducting phase coherence
across the chain is absent, and a voltage threshold for conduction is observed
at the lowest temperatures. We find that Cooper-pair tunneling in such chains
is completely suppressed. Instead, charge transport is dominated by tunneling
of single electrons, which is very sensitive to the presence of BCS
quasiparticles on the superconducting islands of the chain. Consequently we
observe a strong parity effect, where the threshold voltage vanishes sharply at
a characteristic parity temperature , which is significantly lower than
the the critical temperature, . A measurable and thermally-activated
zero-bias conductance appears above , with an activation energy equal to
the superconducting gap, confirming the role of thermally-excited
quasiparticles. Conduction below and above the voltage threshold occurs
via injection of single electrons/holes into the Cooper-pair insulator, forming
a non-equilibrium steady state with a significantly enhanced effective
temperature. Our results explicitly show that single-electron transport
dominates deep in the insulating state of Josephson-junction arrays. This
conduction process has mostly been ignored in previous studies of both
superconducting junction arrays and granular superconducting films below the
superconductor-insulator quantum phase transition.Comment: 8 pages, 6 figure
Analysis of Elliptically Polarized Maximally Entangled States for Bell Inequality Tests
When elliptically polarized maximally entangled states are considered, i.e.,
states having a non random phase factor between the two bipartite polarization
components, the standard settings used for optimal violation of Bell
inequalities are no longer adapted. One way to retrieve the maximal amount of
violation is to compensate for this phase while keeping the standard Bell
inequality analysis settings. We propose in this paper a general theoretical
approach that allows determining and adjusting the phase of elliptically
polarized maximally entangled states in order to optimize the violation of Bell
inequalities. The formalism is also applied to several suggested experimental
phase compensation schemes. In order to emphasize the simplicity and relevance
of our approach, we also describe an experimental implementation using a
standard Soleil-Babinet phase compensator. This device is employed to correct
the phase that appears in the maximally entangled state generated from a
type-II nonlinear photon-pair source after the photons are created and
distributed over fiber channels.Comment: 8 page
Superconducting on-chip spectrometer for mesoscopic quantum systems
15 pages, 12 figuresSpectroscopy is a powerful tool to probe physical, chemical, and biological systems. Recent advances in microfabrication have introduced novel, intriguing mesoscopic quantum systems including superconductor-semiconductor hybrid devices and topologically non-trivial electric circuits. A sensitive, general purpose spectrometer to probe the energy levels of these systems is lacking. We propose an on-chip absorption spectrometer functioning well into the millimeter wave band which is based on a voltage-biased superconducting quantum interference device. We demonstrate the capabilities of the spectrometer by coupling it to a variety of superconducting systems, probing phenomena such as quasiparticle and plasma excitations. We perform spectroscopy of a microscopic tunable non-linear resonator in the 40-50 GHz range and measure transitions to highly excited states. The Josephson junction spectrometer, with unprecedented frequency range, sensitivity, and coupling strength will enable new experiments in linear and non-linear spectroscopy of novel mesoscopic systems