261 research outputs found
Unveiling the orbital angular momentum and acceleration of electron beams
New forms of electron beams have been intensively investigated recently,
including vortex beams carrying orbital angular momentum, as well as Airy beams
propagating along a parabolic trajectory. Their traits may be harnessed for
applications in materials science, electron microscopy and interferometry, and
so it is important to measure their properties with ease. Here we show how one
may immediately quantify these beams' parameters without need for additional
fabrication or non-standard microscopic tools. Our experimental results are
backed by numerical simulations and analytic derivation.Comment: 2 figures in text, 2 in supplementar
Nanograting orientation influence on stress induced by femtosecond laser in fused silica
Under certain conditions, femtosecond lasers can be used to introduce self-organized nanogratings in the bulk of fused silica. Here, we report that the nanogratings orientation influences the induced stress distribution around laser affected zones
Materials processing with tightly focused femtosecond vortex laser beams
This letter is the first demonstration of material modification using tightly
focused femtosecond laser vortex beams. Double-charge femtosecond vortices were
synthesized with the polarization-singularity beam converter described in Ref
[1] and then focused using moderate and high numerical aperture optics (viz.,
NA = 0.45 and 0.9) to ablate fused silica and soda-lime glasses. By controlling
the pulse energy we consistently machine high-quality micron-size ring-shaped
structures with less than 100 nm uniform groove thickness.Comment: 8 pages, 3 figures, 10 references; submitted to Appl. Phys. Lett. on
May 31, 201
Polarization-sensitive photophoresis
We photophoretically trap spherical airborne particles using a single radially or azimuthally polarized laser beam and show that the trapping efficiency is significantly higher for the radial polarization. The demonstrated polarization sensitivity of the photophoretic force, which is caused by polarization-dependent reflection from the particles, adds additional flexibility to the optical micromanipulation of light absorbing particles in gaseous media
Ultrafast laser writing in transparent materials: from physics to applications
Properties of optical materials can be modified with sub-wavelength precision using intense ultrashort light pulses. New science and emerging applications of ultrafast laser writing in transparent materials are reviewed
Control of the Onset of Filamentation in Condensed Media
Propagation of intense, ultrashort laser pulses through condensed media like
crystals of BaF and sapphire results in the formation of filaments. We
demonstrate that the onset of filamentation may be controlled by rotating the
plane of polarization of incident light. We directly visualize filamentation in
BaF_2 via six-photon absorption-induced fluorescence and, concomitantly, by
probing the spectral and spatial properties of white light that is generated.Comment: To appear in Phys. Rev.
Toward deterministic sources: Photon generation in a fiber-cavity quantum memory
We demonstrate the generation of photons within a fiber-cavity quantum
memory, followed by later on-demand readout. Signal photons are generated by
spontaneous four-wave mixing in a fiber cavity comprising a birefringent fiber
with dichroic reflective end facets. The detection of the partner herald photon
indicates the creation of the stored signal photon. After a delay, the signal
photon is switched out of resonance with the fiber cavity by intracavity
frequency translation using Bragg scattering four-wave mixing, driven by
ancillary control pulses. We measure sub-Poissonian statistics in the output
signal mode, with in the first readout bin and a readout
frequency translation efficiency of 80%. The 1/e memory lifetime is
67 cavity cycles, or 1.68s. In an alternate fiber cavity, we show
a strategy for noise reduction and measure after one
cavity cycle.Comment: 6 pages, 3 figure
Engineering optical anisotropy in nonlinear crystals with ultrafast light
Photonic technology is widely based on anisotropic (and) nonlinear materials, which allow light modulation and parametric light conversion. Because the number of naturally occurring crystals is limited, there is a growing demand for artificial metamaterials with optical properties specifically tailored to a given application. Here, we utilize the top-down method to synthesize sub-wavelength periodic
nanostructures inside a uniaxial optically nonlinear crystal (lithium niobate, LiNbO3) by irradiating it with multiple femtosecond laser
pulses. By superimposing form-birefringence associated with the light-induced nanostructures onto natural birefringence of the host crystal
we create macroscopic domains of a biaxial metamaterial embedded into otherwise uniaxial medium.The authors acknowledge the financial support from the
Australian Research Council. W.K. acknowledges support from the
Qatar National Research Fund (No. NPRP12S-0205-190047). P.K.
thanks the Polish Ministry of Science and Higher Education for the
“Mobility Plus” scholarshi
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