595 research outputs found
Observation of quantum jumps in a superconducting artificial atom
A continuously monitored quantum system prepared in an excited state will
decay to its ground state with an abrupt jump. The jump occurs stochastically
on a characteristic time scale T1, the lifetime of the excited state. These
quantum jumps, originally envisioned by Bohr, have been observed in trapped
atoms and ions, single molecules, photons, and single electrons in cyclotrons.
Here we report the first observation of quantum jumps in a macroscopic quantum
system, in our case a superconducting "artificial atom" or quantum bit (qubit)
coupled to a superconducting microwave cavity. We use a fast, ultralow-noise
parametric amplifier to amplify the microwave photons used to probe the qubit
state, enabling continuous high-fidelity monitoring of the qubit. This
technique represents a major step forward for solid state quantum information
processing, potentially enabling quantum error correction and feedback, which
are essential for building a quantum computer. Our technology can also be
readily integrated into hybrid circuits involving molecular magnets, nitrogen
vacancies in diamond, or semiconductor quantum dots.Comment: Updated draft including supplementary information. 8 pages, 6
figures. Supplementary videos are available on our website at
http://physics.berkeley.edu/research/siddiqi/docs/supps
Force-detected nuclear double resonance between statistical spin polarizations
We demonstrate nuclear double resonance for nanometer-scale volumes of spins
where random fluctuations rather than Boltzmann polarization dominate. When the
Hartmann-Hahn condition is met in a cross-polarization experiment, flip-flops
occur between two species of spins and their fluctuations become coupled. We
use magnetic resonance force microscopy to measure this effect between 1H and
13C spins in 13C-enriched stearic acid. The development of a cross-polarization
technique for statistical ensembles adds an important tool for generating
chemical contrast in nanometer-scale magnetic resonance.Comment: 14 pages, 4 figure
Millikelvin thermal and electrical performance of lossy transmission line filters
We report on the scattering parameters and Johnson noise emission of low-pass
stripline filters employing a magnetically loaded silicone dielectric down to
25 mK. The transmission characteristic of a device with =1.3 GHz
remains essentially unchanged upon cooling. Another device with =0.4
GHz, measured in its stopband, exhibits a steady state noise power emission
consistent with a temperature difference of a few mK relative to a
well-anchored cryogenic microwave attenuator at temperatures down to 25 mK,
thus presenting a matched thermal load.Comment: 4 pages, 4 figure
Hybridization-driven gap in U3Bi4Ni3: a 209Bi NMR/NQR study
We report 209Bi NMR and NQR measurements on a single crystal of the Kondo
insulator U3Bi4Ni3. The 209Bi nuclear spin-lattice relaxation rate ()
shows activated behavior and is well-fit by a spin gap of 220 K. The 209Bi
Knight shift (K) exhibits a strong temperature dependence arising from 5f
electrons, in which K is negative at high temperatures and increases as the
temperature is lowered. Below 50 K, K shows a broad maximum and decreases
slightly upon further cooling. Our data provide insight into the evolution of
the hyperfine fields in a fully gapped Kondo insulator based on 5f electron
hybridization.Comment: 4 pages, 4 figures, submitted to Phys. Rev.
Nuclear spin relaxation induced by a mechanical resonator
We report on measurements of the spin lifetime of nuclear spins strongly
coupled to a micromechanical cantilever as used in magnetic resonance force
microscopy. We find that the rotating-frame correlation time of the statistical
nuclear polarization is set by the magneto-mechanical noise originating from
the thermal motion of the cantilever. Evidence is based on the effect of three
parameters: (1) the magnetic field gradient (the coupling strength), (2) the
Rabi frequency of the spins (the transition energy), and (3) the temperature of
the low-frequency mechanical modes. Experimental results are compared to
relaxation rates calculated from the spectral density of the magneto-mechanical
noise.Comment: 4 pages, 4 figure
Heralded state preparation in a superconducting qubit
We demonstrate high-fidelity, quantum nondemolition, single-shot readout of a
superconducting flux qubit in which the pointer state distributions can be
resolved to below one part in 1000. In the weak excitation regime, continuous
measurement permits the use of heralding to ensure initialization to a fiducial
state, such as the ground state. This procedure boosts readout fidelity to
93.9% by suppressing errors due to spurious thermal population. Furthermore,
heralding potentially enables a simple, fast qubit reset protocol without
changing the system parameters to induce Purcell relaxation.Comment: 5 pages, 5 figure
Dynamics of Overhauser Field under nuclear spin diffusion in a quantum dot
The coherence of electron spin can be significantly enhanced by locking the
Overhauser field from nuclear spins using the nuclear spin preparation. We
propose a theoretical model to calculate the long time dynamics of the
Overhauser field under intrinsic nuclear spin diffusion in a quantum dot. We
obtain a simplified diffusion equation that can be numerically solved and show
quantitatively how the Knight shift and the electron-mediated nuclear spin
flip-flop affect the nuclear spin diffusion. The results explain several recent
experimental observations, where the decay time of Overhauser field is measured
under different configurations, including variation of the external magnetic
field, the electron spin configuration in a double dot, and the initial nuclear
spin polarization rate.Comment: 6 pages, 5 figure
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