9,133 research outputs found
Propellant tank pressurization system Patent
Method and apparatus for pressurizing propellant tanks used in propulsion motor feed syste
Calibration of the high-frequency magnetic fluctuation diagnostic in plasma devices
The increasing reservoirs of energetic particles which drive high-frequency modes, together with advances in the understanding of magnetohydrodynamics, have led to a need for higher-frequency (50 kHz to >20MHz) measurements of magnetic field fluctuations in magnetic fusion devices such as tokamaks. This article uses transmission line equations to derive the voltage response of a Mirnov coil at the digitizer end of a transmission line of length ℓ. It is shown that, depending on the terminations of the line, resonances can occur even for ℓ/λ⪡1, with λ the wavelength of a fluctuation in the transmission line. A lumped-circuit model based on the approach of Heeter et al. [R. F. Heeter, A. F. Fasoli, S. Ali-Arshad, and J. M. Moret. Rev. Sci. Instrum.71, 4092 (2000)] is extended to enable the inclusion simultaneously of both serial resistance and parallel conductance elements. As originally proposed by Heeter et al. the lumped-circuit model offers the advantage of remote calibration; this may be of particular value when upgrading existing systems to operate at frequencies above the original design specification. It is formally shown that the transmission line equations for the transfer function and measured impedance reduce to those of the lumped circuit model of Heeter et al. under specific conditions. The result extends the use of the lumped-circuit model of Heeter et al., which can be used to extract the transfer function from measurement of the impedance, beyond the case of an open-circuit termination. Although the numerical procedure does exhibit some problems associated with non-uniqueness, it provides a simple calibration method for systems that are not well defined. Using typical parameters for a high-frequency Mirnov coil installed on the Joint European Torus (JET) tokamak, the lumped-circuit approximation agrees with the steady-state transmission line model to within 0.015° in phase and 22% in amplitude for frequencies up to 1 MHz. A matched termination, though eliminating line resonances and reducing the length of time for the system to reach steady state, is inappropriate for the JET-type coils which exhibit significant temperature-dependent resistance. Finally, for fluctuations of finite duration, a method of computing the discrepancy due to the simplifying assumption of Fourier-stationary conditions is described.This work was funded jointly by the United Kingdom
Engineering and Physical Sciences Research Council and by EURATOM
A quantum reactive scattering perspective on electronic nonadiabaticity
Based on quantum reactive-scattering theory, we propose a method for studying
the electronic nonadiabaticity in collision processes involving electron-ion
rearrangements. We investigate the state-to-state transition probability for
electron-ion rearrangements with two comparable approaches. In the first
approach the information of the electron is only contained in the ground-state
Born-Oppenheimer potential-energy surface, which is the starting point of
common reactive-scattering calculations. In the second approach, the electron
is explicitly taken into account and included in the calculations at the same
level as the ions. Hence, the deviation in the results between the two
approaches directly reflects the electronic nonadiabaticity during the
collision process. To illustrate the method, we apply it to the well-known
proton-transfer model of Shin and Metiu (one electron and three ions),
generalized by us in order to allow for reactive scattering channels. It is
shown that our explicit electron approach is able to capture electronic
nonadiabaticity and the renormalization of the reaction barrier near the
classical turning points of the potential in nuclear configuration space. In
contrast, system properties near the equilibrium geometry of the asymptotic
scattering channels are hardly affected by electronic nonadiabatic effects. We
also present an analytical expression for the transition amplitude of the
asymmetric proton-transfer model based on the direct evaluation of integrals
over the involved Airy functions.Comment: 14 page
Spin squeezing of atomic ensembles by multi-colour quantum non-demolition measurements
We analyze the creation of spin squeezed atomic ensembles by simultaneous
dispersive interactions with several optical frequencies. A judicious choice of
optical parameters enables optimization of an interferometric detection scheme
that suppresses inhomogeneous light shifts and keeps the interferometer
operating in a balanced mode that minimizes technical noise. We show that when
the atoms interact with two-frequency light tuned to cycling transitions the
degree of spin squeezing scales as where is the
resonant optical depth of the ensemble. In real alkali atoms there are loss
channels and the scaling may be closer to Nevertheless
the use of two-frequencies provides a significant improvement in the degree of
squeezing attainable as we show by quantitative analysis of non-resonant
probing on the Cs D1 line. Two alternative configurations are analyzed: a
Mach-Zehnder interferometer that uses spatial interference, and an interaction
with multi-frequency amplitude modulated light that does not require a spatial
interferometer.Comment: 7 figure
Genome-wide analysis of innate electric shock- and odour-avoidance, punishment- and relief- learning
Coloring random graphs
We study the graph coloring problem over random graphs of finite average
connectivity . Given a number of available colors, we find that graphs
with low connectivity admit almost always a proper coloring whereas graphs with
high connectivity are uncolorable. Depending on , we find the precise value
of the critical average connectivity . Moreover, we show that below
there exist a clustering phase in which ground states
spontaneously divide into an exponential number of clusters and where the
proliferation of metastable states is responsible for the onset of complexity
in local search algorithms.Comment: 4 pages, 1 figure, version to app. in PR
Some Helpful Background for the Incoming Tenant
If you are reading this note, I am most likely dead and you are the new tenant or tenants at #172B Meriwether Terrace. Under the circumstances, I’m sure you’ll forgive me for taking the liberty of sharing some historical information about your future home, which was my former home, and before that belonged to a deranged postal worker who went to the loony bin for hoarding undelivered mail. After all, if you’ve found this letter, it means you were poking around beneath the shelving paper, probably searching for a suicide note or dirty pictures or whatever. Well, you can stop searching—for a suicide note, that is. Because I didn’t leave one. Unless you count this memo, which you shouldn’t, since I’m writing this for your benefit, not for mine. To give you context. A person only writes a suicide note if she has someone she wants to leave a message for—someone she knows personally, I mean— and the sad reality is that I don’t. Not even a cat. Of course, I do realize that I’m not the first fifty-eight year old woman to drink a gallon of bleach on account of a man, although I do think I’ve had better reasons that most. But like I said, this isn’t about me..
Capturing Vacuum Fluctuations and Photon Correlations in Cavity Quantum Electrodynamics with Multi-Trajectory Ehrenfest Dynamics
We describe vacuum fluctuations and photon-field correlations in interacting
quantum mechanical light-matter systems, by generalizing the application of
mixed quantum-classical dynamics techniques. We employ the multi-trajectory
implementation of Ehrenfest mean field theory, traditionally developed for
electron-nuclear problems, to simulate the spontaneous emission of radiation in
a model quantum electrodynamical cavity-bound atomic system. We investigate the
performance of this approach in capturing the dynamics of spontaneous emission
from the perspective of both the atomic system and the cavity photon field,
through a detailed comparison with exact benchmark quantum mechanical
observables and correlation functions. By properly accounting for the quantum
statistics of the vacuum field, while using mixed quantum-classical (mean
field) trajectories to describe the evolution, we identify a surprisingly
accurate and promising route towards describing quantum effects in realistic
correlated light-matter systems
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