15,232 research outputs found
Absence of jump discontinuity in the magnetization in quasi-one-dimensional random-field Ising models
We consider the zero-temperature random-field Ising model in the presence of
an external field, on ladders and in one dimension with finite range
interactions, for unbounded continuous distributions of random fields, and show
that there is no jump discontinuity in the magnetizations for any quasi-one
dimensional model. We show that the evolution of the system at an external
field can be described by a stochastic matrix and the magnetization can be
obtained using the eigenvector of the matrix corresponding to the eigenvalue
one, which is continuous and differentiable function of the external field.Comment: 4 pages, 5 ps figures. Minor correction
Solar cell grid patterns
A grid pattern is described for a solar cell of the type which includes a semiconductive layer doped to a first polarity and a top counter-doped layer. The grid pattern comprises a plurality of concentric conductive grids of selected geometric shapes which are centered about the center of the exposed active surface of the counter-doped layer. Connected to the grids is one or more conductors which extend to the cell's periphery. For the pattern area, the grids and conductors are arranged in the pattern to minimize the maximum distance which any injected majority carriers have to travel to reach any of the grids or conductors. The pattern has a multiaxes symmetry with respect to the cell center to minimize the maximum temperature differentials between points on the cell surface and to provide a more uniform temperature distribution across the cell face
Effects of storage temperatures on silicon solar cell contacts
Effect of high humidity and temperature on electrical and mechanical properties of stored silicon solar cell contact
Short note on the excitonic Mott phase
An exciton gas on a lattice is analyzed in terms of a convergent hopping
expansion. For a given chemical potential our calculation provides a sufficient
condition for the hopping rate to obtain an exponential decay of the exciton
correlation function. This result indicates the existence of a Mott phase in
which strong fluctuations destroy the long range correlations in the exciton
gas at any temperature, either by thermal or by quantum fluctuations.Comment: 5 pages, 1 figur
Spectrum of light scattering from an extended atomic wave packet
The spectrum of the light scattered from an extended atomic wave packet is
calculated. For a wave packet consisting of two spatially separated peaks
moving on parallel trajectories, the spectrum contains Ramsey-like fringes that
are sensitive to the phase difference between the two components of the wave
packet. Using this technique, one can establish the mutual coherence of the two
components of the wave packet without recombining them.Comment: 4 page
Solid-State Nuclear Spin Quantum Computer Based on Magnetic Resonance Force Microscopy
We propose a nuclear spin quantum computer based on magnetic resonance force
microscopy (MRFM). It is shown that an MRFM single-electron spin measurement
provides three essential requirements for quantum computation in solids: (a)
preparation of the ground state, (b) one- and two- qubit quantum logic gates,
and (c) a measurement of the final state. The proposed quantum computer can
operate at temperatures up to 1K.Comment: 16 pages, 5 figure
Sensitive linear response of an electron-hole superfluid in a periodic potential
We consider excitons in a two-dimensional periodic potential and study the
linear response of the excitonic superfluid to an electromagnetic wave at low
and high densities. It turns out that the static structure factor for small
wavevectors is very sensitive to a change of density and temperature. It is a
consequence of the fact that thermal fluctuations play a crucial role at small
wavevectors, since exchanging the order of the two limits, zero temperature and
vanishing wavevector, leads to different results for the structure factor. This
effect could be used for high accuracy measurements in the superfluid exciton
phase, which might be realized by a gated electron-hole gas. The transition of
the exciton system from the superfluid state to a non-superfluid state and its
manifestation by light scattering are discussed.Comment: 9 pages, 5 figure
Gaussian approximation and single-spin measurement in OSCAR MRFM with spin noise
A promising technique for measuring single electron spins is magnetic
resonance force microscopy (MRFM), in which a microcantilever with a permanent
magnetic tip is resonantly driven by a single oscillating spin. If the quality
factor of the cantilever is high enough, this signal will be amplified over
time to the point that it can be detected by optical or other techniques. An
important requirement, however, is that this measurement process occur on a
time scale short compared to any noise which disturbs the orientation of the
measured spin. We describe a model of spin noise for the MRFM system, and show
how this noise is transformed to become time-dependent in going to the usual
rotating frame. We simplify the description of the cantilever-spin system by
approximating the cantilever wavefunction as a Gaussian wavepacket, and show
that the resulting approximation closely matches the full quantum behavior. We
then examine the problem of detecting the signal for a cantilever with thermal
noise and spin with spin noise, deriving a condition for this to be a useful
measurement.Comment: 12 pages, 8 figures in EPS format, RevTeX 4.
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