94,444 research outputs found
A Novel Nanocomposite with Photo-Polymerization for Wafer Level Application
©2008 IEEE. Personal use of this material is permitted. However, permission to reprint/republish this material for advertising or promotional purposes or for creating new collective works for resale or distribution to servers or lists, or to reuse any copyrighted component of this work in other works must be obtained from the IEEE. This material is presented to ensure timely dissemination of scholarly and technical work. Copyright and all rights therein are retained by authors or by other copyright holders. All persons copying this information are expected to adhere to the terms and constraints invoked by each author's copyright. In most cases, these works may not be reposted without the explicit permission of the copyright holder.A novel nanocomposite photo-curable material which can act both as a photoresist and a stress redistribution layer applied on the wafer level was synthesized and studied. In the experiments, 20-nm silica fillers were modified by a silane coupling agent through a hydrolysis and condensation reaction and then incorporated into the epoxy matrix. A photo-sensitive initiator was added into the formulation which can release cations after ultraviolet exposure and initiate the epoxy crosslinking reaction. The photo-crosslinking reaction of the epoxy made it a negative tone photoresist. The curing reaction of the nanocomposites was monitored by a differential scanning calorimeter with the photo-calorimetric accessory. The thermal mechanical properties of photo-cured nanocomposites thin film were also measured. It was found that the moduli change of the nanocomposites as the filler loading increasing did not follow the Mori–Tanaka model, which indicated that the nanocomposite was not a simple two-phase structure as the composite with micron size filler. The addition of nano-sized silica fillers reduced the thermal expansion and improved the stiffness of the epoxy, with only a minimal effect on the optical transparency of the epoxy, which facilitated the complete photo reaction in the epoxy
Formation and Stability of Cellular Carbon Foam Structures:An {\em Ab Initio} Study
We use ab initio density functional calculations to study the formation and
structural as well as thermal stability of cellular foam-like carbon
nanostructures. These systems with a mixed bonding character may be
viewed as bundles of carbon nanotubes fused to a rigid contiguous 3D honeycomb
structure that can be compressed more easily by reducing the symmetry of the
honeycombs. The foam may accommodate the same type of defects as graphene, and
its surface may be be stabilized by terminating caps. We postulate that the
foam may form under non-equilibrium conditions near grain boundaries of a
carbon-saturated metal surface
Formation of Compressed Flat Electron Beams with High Transverse-Emittance Ratios
Flat beams -- beams with asymmetric transverse emittances -- have important
applications in novel light-source concepts, advanced-acceleration schemes and
could possibly alleviate the need for damping rings in lepton colliders. Over
the last decade, a flat-beam-generation technique based on the conversion of an
angular-momentum-dominated beam was proposed and experimentally tested. In this
paper we explore the production of compressed flat beams. We especially
investigate and optimize the flat-beam transformation for beams with
substantial fractional energy spread. We use as a simulation example the
photoinjector of the Fermilab's Advanced Superconducting Test Accelerator
(ASTA). The optimizations of the flat beam generation and compression at ASTA
were done via start-to-end numerical simulations for bunch charges of 3.2 nC,
1.0 nC and 20 pC at ~37 MeV. The optimized emittances of flat beams with
different bunch charges were found to be 0.25 {\mu}m (emittance ratio is ~400),
0.13 {\mu}m, 15 nm before compression, and 0.41 {\mu}m, 0.20 {\mu}m, 16 nm
after full compression, respectively with peak currents as high as 5.5 kA for a
3.2-nC flat beam. These parameters are consistent with requirements needed to
excite wakefields in asymmetric dielectric-lined waveguides or produce
significant photon flux using small-gap micro-undulators.Comment: 17
Effects of Minijets on Hadronic Spectra and Azimuthal Harmonics in Au-Au Collisions at 200 GeV
The production of hadrons in heavy-ion collisions at RHIC in the low
transverse-momentum () region is investigated in the recombination model
with emphasis on the effects of minijets on the azimuthal anisotropy. Since the
study is mainly on the hadronization of partons at late time, the fluid picture
is not used to trace the evolution of the system. The inclusive distributions
at low are determined as the recombination products of thermal partons.
The dependencies of both pion and proton have a common exponential factor
apart from other dissimilar kinematic and resonance factors, because they are
inherited from the same pool of thermal partons. Instead of the usual
description based on hydrodynamics, the azimuthal anisotropy of the produced
hadrons is explained as the consequence of the effects of minijets, either
indirectly through the recombination of enhanced thermal partons in the
vicinity of the trajectories of the semihard partons, or directly through
thermal-shower recombination. Although our investigation is focussed on the
single-particle distribution at midrapidity, we give reasons why a component in
that distribution can be identified with the ridge, which together with the
second harmonic is due to the semihard partons created near the medium
surface that lead to calculable anisotropy in . It is shown that the
higher azimuthal harmonics, , can also be well reproduced without
reference to flow. The and centrality dependencies of the higher
harmonics are prescribed by the interplay between TT and TS recombination
components. The implication of the success of this drastic departure from the
conventional approach is discussed.Comment: 28 pages and 8 figures, more discussions and references adde
Time-dependent Fr\"ohlich transformation approach for two-atom entanglement generated by successive passage through a cavity
Time-dependent Fr\"ohlich transformations can be used to derive an effective
Hamiltonian for a class of quantum systems with time-dependent perturbations.
We use such a transformation for a system with time-dependent atom-photon
coupling induced by the classical motion of two atoms in an inhomogeneous
electromagnetic field. We calculate the entanglement between the two atoms
resulting from their motion through a cavity as a function of their initial
position difference and velocity.Comment: 7 pages, 3 figure
Continuous quantum phase transition in a Kondo lattice model
We study the magnetic quantum phase transition in an anisotropic Kondo
lattice model. The dynamical competition between the RKKY and Kondo
interactions is treated using an extended dynamic mean field theory (EDMFT)
appropriate for both the antiferromagnetic and paramagnetic phases. A quantum
Monte Carlo approach is used, which is able to reach very low temperatures, of
the order of 1% of the bare Kondo scale. We find that the finite-temperature
magnetic transition, which occurs for sufficiently large RKKY interactions, is
first order. The extrapolated zero-temperature magnetic transition, on the
other hand, is continuous and locally critical.Comment: 4 pages, 4 figures; updated, to appear in PR
Resonant activation: a strategy against bacterial persistence
A bacterial colony may develop a small number of cells genetically identical
to, but phenotypically different from other normally growing bacteria. These
so-called persister cells keep themselves in a dormant state and thus are
insensitive to antibiotic treatment, resulting in serious problems of drug
resistance. In this paper, we proposed a novel strategy to "kill" persister
cells by triggering them to switch, in a fast and synchronized way, into
normally growing cells that are susceptible to antibiotics. The strategy is
based on resonant activation (RA), a well-studied phenomenon in physics where
the internal noise of a system can constructively facilitate fast and
synchronized barrier crossings. Through stochastic Gilliespie simulation with a
generic toggle switch model, we demonstrated that RA exists in the phenotypic
switching of a single bacterium. Further, by coupling single cell level and
population level simulations, we showed that with RA, one can greatly reduce
the time and total amount of antibiotics needed to sterilize a bacterial
population. We suggest that resonant activation is a general phenomenon in
phenotypic transition, and can find other applications such as cancer therapy.Comment: 21 pages, 12 figures, submitte
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