40 research outputs found
Coherence of Nitrogen-Vacancy Electronic Spin Ensembles in Diamond
We present an experimental and theoretical study of electronic spin
decoherence in ensembles of nitrogen-vacancy (NV) color centers in bulk
high-purity diamond at room temperature. Under appropriate conditions, we find
ensemble NV spin coherence times (T_2) comparable to that of single NVs, with
T_2 > 600 microseconds for a sample with natural abundance of 13C and
paramagnetic impurity density ~10^15 cm^(-3). We also observe a sharp decrease
of the coherence time with misalignment of the static magnetic field relative
to the NV electronic spin axis, consistent with theoretical modeling of NV
coupling to a 13C nuclear spin bath. The long coherence times and increased
signal-to-noise provided by room-temperature NV ensembles will aid many
applications of NV centers in precision magnetometry and quantum information.Comment: 5 pages, 3 figures; v2 minor correction
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Anti-Reflection Coating for Nitrogen-Vacancy Optical Measurements in Diamond
We realize anti-reflection (AR) coatings for optical excitation and fluorescence measurements of nitrogen-vacancy (NV) color centers in bulk diamond by depositing quarter-wavelength thick silica layers on the diamondsurface. These AR coatings improve NV-diamond optical measurements by reducing optical reflection at the diamond-air interface from ≈17% to ≈2%, which allows more effective NV optical excitation and more efficient detection of NV fluorescence. We also show that diamondAR coatings eliminate standing-wave interference patterns of excitation laser intensity within bulk diamond, and thereby greatly reduce spatial variations in NV fluorescence, which can degrade spatially resolved magnetic field sensing using NV centers.Engineering and Applied SciencesPhysic
Cryogenic sapphire oscillator with exceptionally high long-term frequency stability
We report on the development of a sapphire cryogenic microwave resonator
oscillator long-term fractional frequency stability of 2x10^-17Sqrt[\tau] for
integration times \tau>10^3 s and negative drift of about 2.2x10^-15/day. The
short-term frequency instability of the oscillator is highly reproducible and
also state-of-the-art: 5.6x10^-16 for an integration time of \tau ~ 20 s.Comment: Accepted for publication in Applied Physics Letter
On the experimental determination of the one-way speed of light
In this contribution the question of the isotropy of the one-way speed of
light from an experimental perspective is addressed. In particular, we analyze
two experimental methods commonly used in its determination. The analysis is
aimed at clarifying the view that the one-way speed of light cannot be
determined by techniques in which physical entities close paths. The procedure
employed here will provide epistemological tools such that physicists
understand that a direct measurement of the speed not only of light but of any
physical entity is by no means trivial. Our results shed light on the physics
behind the experiments which may be of interest for both physicists with an
elemental knowledge in special relativity and philosophers of science.Comment: 8 pages, 5 figures. To appear in the European Journal of Physic
Magnetic field imaging with nitrogen-vacancy ensembles
Part of Focus on Diamond-Based Photonics and Spintronics
We demonstrate a method of imaging spatially varying magnetic fields using a thin layer of nitrogen-vacancy (NV) centers at the surface of a diamond chip. Fluorescence emitted by the two-dimensional NV ensemble is detected by a CCD array, from which a vector magnetic field pattern is reconstructed. As a demonstration, ac current is passed through wires placed on the diamond chip surface, and the resulting ac magnetic field patterns are imaged using an echo-based technique with sub-micron resolution over a 140 μm×140 μm field of view, giving single-pixel sensitivity \sim100\,{\rm nT}/\sqrt{{\rm Hz}} . We discuss ongoing efforts to further improve the sensitivity, as well as potential bioimaging applications such as real-time imaging of activity in functional, cultured networks of neurons.
PACS
61.72.J- Point defects and defect clusters
78.55.Hx Other solid inorganic materials
87.50.C- Static and low-frequency electric and magnetic fields effects
85.30.Tv Field effect devices
Subjects
Electronics and devices
Condensed matter: electrical, magnetic and optical
Semiconductors
Medical physics
Biological physics
Condensed matter: structural, mechanical & thermalUnited States. Defense Advanced Research Projects AgencyNational Institute of Standards and Technology (U.S.)National Science Foundation (U.S.
Rotating Odd-Parity Lorentz Invariance Test in Electrodynamics
We report the first operation of a rotating odd-parity Lorentz Invariance
test in electrodynamics using a microwave Mach-Zehnder interferometer with
permeable material in one arm. The experiment sets a direct bound to of . Using new power recycled waveguide
interferometer techniques (with the highest spectral resolution ever achieved
of ) we show an improvement of several orders of
magnitude is attainable in the future
Direct Terrestrial Test of Lorentz Symmetry in Electrodynamics to 10
Lorentz symmetry is a foundational property of modern physics, underlying the
standard model of particles and general relativity. It is anticipated that
these two theories are low energy approximations of a single theory that is
unified and consistent at the Planck scale. Many unifying proposals allow
Lorentz symmetry to be broken, with observable effects appearing at
Planck-suppressed levels; thus precision tests of Lorentz invariance are needed
to assess and guide theoretical efforts. Here, we use ultra-stable oscillator
frequency sources to perform a modern Michelson-Morley experiment and make the
most precise direct terrestrial test to date of Lorentz symmetry for the
photon, constraining Lorentz violating orientation-dependent relative frequency
changes / to 9.210.7 (95 confidence
interval). This order of magnitude improvement over previous Michelson-Morley
experiments allows us to set comprehensive simultaneous bounds on nine boost
and rotation anisotropies of the speed of light, finding no significant
violations of Lorentz symmetry.Comment: 20 pages, 13 figure
Far-field optical imaging and manipulation of individual spins with nanoscale resolution
A fundamental limit to existing optical techniques for measurementand manipulation of spin degrees of freedom is set by diffraction, which does not allow spins separated by less than about a quarter of a micrometre to be resolved using conventional far-field optics. Here, we report an efficient far-field optical technique that overcomes the limiting role of diffraction, allowing individual electronic spins to be detected, imaged and manipulated coherently with nanoscale resolution. The technique involves selective flipping of the orientation of individual spins, associated with nitrogen-vacancy centres in room-temperature diamond, using a focused beam of light with intensity vanishing at a controllable location, which enables simultaneous single-spin imaging and magnetometry at the nanoscale with considerably less power than conventional techniques. Furthermore, by inhibiting spin transitions away from the laser intensity null, selective coherent rotation of individual spins is realized. This technique can be extended to subnanometre dimensions, thus enabling applications in diverse areas ranging from quantum information science to bioimaging
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Far-Field Optical Imaging and Manipulation of Individual Spins with Nanoscale Resolution
A fundamental limit to existing optical techniques for measurementand manipulation of spin degrees of freedom is set by diffraction, which does not allow spins separated by less than about a quarter of a micrometre to be resolved using conventional far-field optics. Here, we report an efficient far-field optical technique that overcomes the limiting role of diffraction, allowing individual electronic spins to be detected, imaged and manipulated coherently with nanoscale resolution. The technique involves selective flipping of the orientation of individual spins, associated with nitrogen-vacancy centres in room-temperature diamond, using a focused beam of light with intensity vanishing at a controllable location, which enables simultaneous single-spin imaging and magnetometry at the nanoscale with considerably less power than conventional techniques. Furthermore, by inhibiting spin transitions away from the laser intensity null, selective coherent rotation of individual spins is realized. This technique can be extended to subnanometre dimensions, thus enabling applications in diverse areas ranging from quantum information science to bioimaging.Physic