15,171 research outputs found
Photonic crystal nanofiber using an external grating
We implement a photonic crystal nanofiber device by reversibly combining an
optical nanofiber and a nanofabricated grating. Using the finite-difference
time-domain method, we design the system for minimal optical loss while
tailoring the resonant wavelength and bandwidth of the device. Experimentally
we demonstrate that the combined system shows a strong photonic stop-band in
good agreement with numerical predictions. The resulting device may be used to
realize strong light-matter coupling near to the nanofiber surface
Nodal Liquid Theory of the Pseudo-Gap Phase of High-Tc Superconductors
We introduce and study the nodal liquid, a novel zero-temperature quantum
phase obtained by quantum-disordering a d-wave superconductor. It has numerous
remarkable properties which lead us to suggest it as an explanation of the
pseudo-gap state in underdoped high-temperature superconductors. In the absence
of impurities, these include power-law magnetic order, a T-linear spin
susceptibility, non-trivial thermal conductivity, and two- and one-particle
charge gaps, the latter evidenced, e.g. in transport and electron photoemission
(which exhibits pronounced fourfold anisotropy inherited from the d-wave
quasiparticles). We use a 2+1-dimensional duality transformation to derive an
effective field theory for this phase. The theory is comprised of gapless
neutral Dirac particles living at the former d-wave nodes, weakly coupled to
the fluctuating gauge field of a dual Ginzburg-Landau theory. The nodal liquid
interpolates naturally between the d-wave superconductor and the insulating
antiferromagnet, and our effective field theory is powerful enough to permit a
detailed analysis of a panoply of interesting phenomena, including charge
ordering, antiferromagnetism, and d-wave superconductivity. We also discuss the
zero-temperature quantum phase transitions which separate the nodal liquid from
various ordered phases.Comment: 19 pages, 4 figure
Evolution of Primordial Black Holes in Loop Quantum Gravity
In this work, we study the evolution of Primordial Black Holes within the
context of Loop Quantum Gravity. First we calculate the scale factor and energy
density of the universe for different cosmic era and then taking these as
inputs we study evolution of primordial black holes. From our estimation it is
found that accretion of radiation does not affect evolution of primordial black
holes in loop quantum gravity even though a larger number of primordial black
holes may form in early universe in comparison with Einstein's or scalar-tensor
theories.Comment: 8 pages, 1 figur
Performance and Improvement of Various Antennas in Modern Wireless Communication System
Today, the importance of wireless communication is known around the world. To achieve better communication, many techniques and methods have been introduced. Among these techniques, intelligent / adaptive antennas are a hot topic in the field of research. Smart antennas consist of several antenna arrays and are able to optimize the radiation and reception of dynamically desired signals. In order to avoid or mitigate interference, smart antennas may also introduce zero values towards the receivers by adaptively updating the weights associated with each antenna element. Smart antennas can also improve reception quality and reduce missed calls. The various existing surveys are also discussed to identify the research deficit for the scope of future research
Influence of surface roughness on superhydrophobicity
Superhydrophobic surfaces, with liquid contact angle theta greater than 150
degree, have important practical applications ranging from self-cleaning window
glasses, paints, and fabrics to low-friction surfaces. Many biological
surfaces, such as the lotus leaf, have hierarchically structured surface
roughness which is optimized for superhydrophobicity through natural selection.
Here we present a molecular dynamics study of liquid droplets in contact with
self-affine fractal surfaces. Our results indicate that the contact angle for
nanodroplets depends strongly on the root-mean-square surface roughness
amplitude but is nearly independent of the fractal dimension D_f of the
surface.Comment: 5 Pages, 6 figures. Minimal changes with respect to the previous
versio
Correlation between stick-slip frictional sliding and charge transfer
A decade ago, Budakian and Putterman (Phys. Rev. Lett., {\bf 85}, 1000
(2000)) ascribed friction to the formation of bonds arising from contact
charging when a gold tip of a surface force apparatus was dragged on
polymethylmethacrylate surface. We propose a stick-slip model that captures the
observed correlation between stick-slip events and charge transfer, and the
lack of dependence of the scale factor connecting the force jumps and charge
transfer on normal load. Here, stick-slip dynamics arises as a competition
between the visco-elastic and plastic deformation time scales and that due to
the pull speed with contact charging playing a minor role. Our model provides
an alternate basis for explaining most experimental results without ascribing
friction to contact charging.Comment: 8 pages, 4 figures, To be appeared in Physical Review
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