497 research outputs found
Electrostatic waves and anomalous transport in the solar wind
In situ measurements of fluctuation spectra and particle distribution functions have now been carried out throughout interplanetary space. The link between these observations is established by theories of wave particle interaction. Linear instability analysis for the actual nonMaxwellian particle distribution functions and an examination of the velocity dependence of microscopic diffusion coefficients form the basis of such an investigation. It is described in more detail for the short wavelength, ion acoustic like turbulence which is found by linear instability analysis to correspond to the observed electrostatic fluctuations. Of the transport processes associated with these fluctuations, electron heat conduction and electron ion energy transfer are of particular importance for macroscopic solar wind expansion. These effects are studied with the aid of an anomalous transport theory. This theory (Dum, 1978 a,b) is based on the dominance of elastic scattering of electrons by fluctuations, similar to (enhanced) electron ion collisions. It has a much wider range of applicability than classical transport theory, which assumes dominance of Coulomb collisions for elastic and inelastic scattering
Dynamics of magnetosphere-ionosphere coupling including turbulent transport
A two dimensional two-fluid MHD model including anomalous resistivity was used to investigate the dynamics of magnetosphere-ionosphere coupling. When a field-aligned current is generated on auroral field lines, the disturbance propagates towards the ionosphere in the form of a kinetic Alfven wave. When the current exceeds a critical value, microscopic turbulence is produced, which modifies the propagation of the Alfven wave. This process is modeled by a nonlinear collision frequency, which increases with the excess of the drift velocity over the critical value. Turbulence leads to absorption and reflection of the Alfven wave, partially decoupling the generator from the ionosphere. The approach to a steady-state is strongly dependent on the presence or absence of the turbulence. The current is self-limiting, since a current in excess of critical causes a diffusion of the magnetic field perturbation and a reduction of current
Exploring Factors that Enhance Organizational Sustainability: A Case Study of Ningshawng Social Institute, Myitkyina, Kachin State, Myanmar
The aim of this research is to explore factors that influence organizational sustainability of Ningshawng Social Institute. The factors that were examined were community engagement, funding, human resources, leadership and organizational strategy in NSI Organization in Myanmar. The study used a mixed-method design. The participants of the study were NSI staff, top management, and volunteers who were requested to participate in an online survey. Sixty-three (63) answered the questionnaire and analyzed answers from open-ended question for qualitative data results. The researcher utilizes the Cronbach’s Alpha Reliability Test, descriptive analysis, and inferential analysis for quantitative data analysis whereas the qualitative data was open-ended questions that ask the staffs’ opinions for the most needed area to explore factors for NGO sustainability. The results indicated that organizations’ sustainability is influenced by community engagement and human resources. The qualitative data highlight that organizational strategy and funding will improve the sustainability of the organization. Based on the overall result some areas need to develop according to employees’ perspectives of the NSI organization. Therefore, recommendations based on the findings were proposed to enhance NGO sustainability
Retroactive quantum jumps in a strongly-coupled atom-field system
We investigate a novel type of conditional dynamic that occurs in the
strongly-driven Jaynes-Cummings model with dissipation. Extending the work of
Alsing and Carmichael [Quantum Opt. {\bf 3}, 13 (1991)], we present a combined
numerical and analytic study of the Stochastic Master Equation that describes
the system's conditional evolution when the cavity output is continuously
observed via homodyne detection, but atomic spontaneous emission is not
monitored at all. We find that quantum jumps of the atomic state are induced by
its dynamical coupling to the optical field, in order retroactively to justify
atypical fluctuations in ocurring in the homodyne photocurrent.Comment: 4 pages, uses RevTex, 5 EPS figure
Dissipative dynamics of a kink state in a Bose-condensed gas
We develop a theory of dissipative dynamics of a kink state in a
finite-temperature Bose-condensed gas. We find that due to the interaction with
the thermal cloud the kink state accelerates towards the velocity of sound and
continuously transforms to the ground-state condensate. We calculate the
life-time of a kink state in a trapped gas and discuss possible experimental
implications.Comment: 4 pages, RevTe
Detection of vorticity in Bose-Einstein condensed gases by matter-wave interference
A phase-slip in the fringes of an interference pattern is an unmistakable
characteristic of vorticity. We show dramatic two-dimensional simulations of
interference between expanding condensate clouds with and without vorticity. In
this way, vortices may be detected even when the core itself cannot be
resolved.Comment: 3 pages, RevTeX, plus 6 PostScript figure
Cat States and Single Runs for the Damped Harmonic Oscillator
We discuss the fate of initial states of the cat type for the damped harmonic
oscillator, mostly employing a linear version of the stochastic Schr\"odinger
equation. We also comment on how such cat states might be prepared and on the
relation of single realizations of the noise to single runs of experiments.Comment: 18, Revte
Winding up by a quench: vortices in the wake of rapid Bose-Einstein condensation
A second order phase transition induced by a rapid quench can lock out
topological defects with densities far exceeding their equilibrium expectation
values. We use quantum kinetic theory to show that this mechanism, originally
postulated in the cosmological context, and analysed so far only on the mean
field classical level, should allow spontaneous generation of vortex lines in
trapped Bose-Einstein condensates of simple topology, or of winding number in
toroidal condensates.Comment: 4 pages, 2 figures; misprint correcte
Topological phases and circulating states of Bose-Einstein condensates
We show that the quantum topological effect predicted by Aharonov and Casher
(AC effect) [Phys. Rev. Lett. 53, 319 (1984)] may be used to create circulating
states of magnetically trapped atomic Bose-Einstein condensates (BEC). A simple
experimental setup is suggested based on a multiply connected geometry such as
a toroidal trap or a magnetic trap pinched by a blue-detuned laser. We give
numerical estimates of such effects within the current atomic BEC experiments,
and point out some interesting properties of the associated quantized
circulating states.Comment: 4 pages, 3 figures, accepted for publication in Phys. Rev.
- …