14 research outputs found
Superconducting qubit based on twisted cuprate van der Waals heterostructures
Van-der-Waals (vdW) assembly enables the fabrication of novel Josephson
junctions utilizing an atomically sharp interface between two exfoliated and
relatively twisted (Bi2212) flakes. In a range of
twist angles around , the junction provides a regime where the
interlayer two-Cooper pair tunneling dominates the current-phase relation. Here
we propose to employ this novel junction to realize a capacitively shunted
qubit that we call flowermon. The -wave nature of the order parameter endows
the flowermon with inherent protection against charge-noise-induced relaxation
and quasiparticle-induced dissipation. This inherently protected qubit paves
the way to a new class of high-coherence hybrid superconducting quantum devices
based on unconventional superconductors.Comment: 6+5 pages, 4+4 figure
Non-Poissonian Quantum Jumps of a Fluxonium Qubit due to Quasiparticle Excitations
As the energy relaxation time of superconducting qubits steadily improves,
non-equilibrium quasiparticle excitations above the superconducting gap emerge
as an increasingly relevant limit for qubit coherence. We measure fluctuations
in the number of quasiparticle excitations by continuously monitoring the
spontaneous quantum jumps between the states of a fluxonium qubit, in
conditions where relaxation is dominated by quasiparticle loss. Resolution on
the scale of a single quasiparticle is obtained by performing quantum
non-demolition projective measurements within a time interval much shorter than
, using a quantum limited amplifier (Josephson Parametric Converter). The
quantum jumps statistics switches between the expected Poisson distribution and
a non-Poissonian one, indicating large relative fluctuations in the
quasiparticle population, on time scales varying from seconds to hours. This
dynamics can be modified controllably by injecting quasiparticles or by seeding
quasiparticle-trapping vortices by cooling down in magnetic field
Imaging phonon-mediated hydrodynamic flow in WTe2
In the presence of interactions, electrons in condensed-matter systems can
behave hydrodynamically, exhibiting phenomena associated with classical fluids,
such as vortices and Poiseuille flow. In most conductors, electron-electron
interactions are minimized by screening effects, hindering the search for
hydrodynamic materials; however, recently, a class of semimetals has been
reported to exhibit prominent interactions. Here we study the current flow in
the layered semimetal tungsten ditelluride by imaging the local magnetic field
using a nitrogen-vacancy defect in a diamond. We image the spatial current
profile within three-dimensional tungsten ditelluride and find that it exhibits
non-uniform current density, indicating hydrodynamic flow. Our
temperature-resolve current profile measurements reveal a non-monotonic
temperature dependence, with the strongest hydrodynamic effects at
approximately 20 K. We also report ab initio calculations showing that
electron-electron interactions are not explained by the Coulomb interaction
alone, but are predominantly mediated by phonons. This provides a promising
avenue in the search for hydrodynamic flow and prominent electron interactions
in high-carrier-density materials.Comment: 11 pages, 4 figures + supplementary materia
Quantum bits with Josephson junctions
Already in the first edition of this book (Barone and Paterno, "Fundamentals
and Physics and Applications of the Josephson Effect", Wiley 1982), a great
number of interesting and important applications for Josephson junctions were
discussed. In the decades that have passed since then, several new applications
have emerged. This chapter treats one such new class of applications: quantum
optics and quantum information processing (QIP) based on superconducting
circuits with Josephson junctions. In this chapter, we aim to explain the
basics of superconducting quantum circuits with Josephson junctions and
demonstrate how these systems open up new prospects, both for QIP and for the
study of quantum optics and atomic physics.Comment: 30 pages, 10 figures. Book chapter for a new edition of Barone and
Paterno's "Fundamentals and Physics and Applications of the Josephson
Effect". Final versio
Quantum reservoir engineering and single qubit cooling
International audienceStabilizing a quantum system in a desired state has important implications in quantum information science. In control engineering, stabilization is usually achieved by the use of feedback. The closed-loop control paradigm consists of measuring the system in a non-destructive manner, analyzing in real-time the measurement output to estimate the dynamical state and finally, calculating a feedback law to stabilize the desired state. However, the rather short dynamical time-scales of most quantum systems impose important limitations on the complexity of real-time output signal analysis and retroaction. An alternative control approach for quantum state stabilization, bypassing a real-time analysis of output signal, is called reservoir engineering. In this paper, we start with a general description of quantum reservoir engineering. We then apply this method to stabilize the ground state (lowest energy state) of a single two-level quantum system. Applying the averaging theorem and some simple Lyapunov techniques, we prove the convergence of our proposed scheme. This scheme has recently been successfully implemented on a superconducting qubit and has led to a fast and reliable reset protocol for these qubit
Nuclear Spin Assisted Magnetic Field Angle Sensing
Quantum sensing exploits the strong sensitivity of quantum systems to measure
small external signals. The nitrogen-vacancy (NV) center in diamond is one of
the most promising platforms for real-world quantum sensing applications,
predominantly used as a magnetometer. However, its magnetic field sensitivity
vanishes when a bias magnetic field acts perpendicular to the NV axis. Here, we
introduce a novel sensing strategy assisted by the nitrogen nuclear spin that
uses the entanglement between the electron and nuclear spins to restore the
magnetic field sensitivity. This, in turn, allows us to detect small changes in
the magnetic field angle relative to the NV axis. Furthermore, based on the
same underlying principle, we show that the NV coupling strength to magnetic
noise, and hence its coherence time, exhibits a strong asymmetric angle
dependence. This allows us to uncover the directional properties of the local
magnetic environment and to realize maximal decoupling from anisotropic noise.Comment: 15 pages, 4 figures in main text + 11 pages, 8 figures in
supplementary informatio
Preturbulence in momentum-relaxing Navier-Stokes hydrodynamics
6+3 pages, 7 figuresIn a hydrodynamic regime of electronic fluids, the electron scattering on impurities and phonons inhibits the development of oscillating preturbulent phenomena (such as the Kármán vortex shedding) and enforces a laminar flow. Working in a local generalization of the Navier-Stokes hydrodynamics of incompressible two-dimensional fluids, we show that the critical relaxation time separating these two regimes is described by a surprisingly simple fractional power function of the Reynolds number. The critical exponent, α 4/3, sets particular experimental conditions for the observation of preturbulent effects in electronic fluids