399 research outputs found
Heating of solar chromosphere by electromagnetic wave absorption in a plasma slab model
The heating of solar chromospheric inter-network regions by means of the
absorption of electromagnetic (EM) waves that originate from the photospheric
blackbody radiation is studied in the framework of a plasma slab model. The
absorption is provided by the electron-neutral collisions in which electrons
oscillate in the EM wave field and electron-neutral collisions damp the EM
wave. Given the uncertain nature of the collision cross-section due to the
plasma micro-turbulence, it is shown that for plausible physical parameters,
the heating flux produced by the absorption of EM waves in the chromosphere is
between % of the chromospheric radiative loss flux requirement. It is
also established that there is an optimal value for the collision
cross-section, m, that produces the maximal heating
flux of 1990 W m.Comment: Physics of Plasmas, in press, April 2011 issue (final printed
version, typos in proofs corrected
Resolution of the equatorial spread F problem: Revisited
An overview of recent advances made in understanding the phenomenon of equatorial spread F (ESF) is presented and a discussion of unresolved issues that need to be addressed. The focus is on research that has occurred in the last decade. The topics include satellite observations, theory, and modeling. The suggested areas that require further exploration are a unified theory of turbulence extending from 100 s m to 10 s cm, the impact of geomagnetic storms on the development of equatorial spread F, the need for accurate thermospheric wind measurements and models, and identifying the underlying physics of ESF in the post-midnight sector during solar minimum
Fast ignition of fusion targets by laser-driven electrons
We present hybrid PIC simulations of fast electron transport and energy
deposition in pre-compressed fusion targets, taking full account of collective
magnetic effects and the hydrodynamic response of the background plasma.
Results on actual ignition of an imploded fast ignition configuration are shown
accounting for the increased beam divergence found in recent experiments [J.S.
Green et al., Phys. Rev. Lett. 100, 015003 (2008)] and the reduction of the
electron kinetic energy due to profile steepening predicted by advanced PIC
simulations [B. Chrisman et al. Phys. Plasmas 15, 056309 (2008)]. Target
ignition is studied as a function of injected electron energy, distance of
cone-tip to dense core, initial divergence and kinetic energy of the
relativistic electron beam. We found that beam collimation reduces
substantially the ignition energies of the cone-guided fuel configuration
assumed here.Comment: 15 pages, 9 figures. accepted for publication in Plasma Physics and
Controlled Fusio
Particle acceleration in tangential discontinuities by lower hybrid waves
We consider the role that the lower-hybrid wave turbulence plays in providing the necessary resistivity at collisionless reconnection sights. The mechanism for generating the waves is considered to be the lower-hybrid drift instability. We find that the level of the wave amplitude is sufficient enough to heat and accelerate both electrons and ions
Validating Ionospheric Models Against Technologically Relevant Metrics
New, open access tools have been developed to validate ionospheric models in terms of technologically relevant metrics. These are ionospheric errors on GPS 3D position, HF ham radio communications, and peak F-region density. To demonstrate these tools, we have used output from Sami is Another Model of the Ionosphere (SAMI3) driven by high-latitude electric potentials derived from Active Magnetosphere and Planetary Electrodynamics Response Experiment, covering the first available month of operation using Iridium-NEXT data (March 2019). Output of this model is now available for visualization and download via https://sami3.jhuapl.edu. The GPS test indicates SAMI3 reduces ionospheric errors on 3D position solutions from 1.9 m with no model to 1.6 m on average (maximum error: 14.2 m without correction, 13.9 m with correction). SAMI3 predicts 55.5% of reported amateur radio links between 2–30 MHz and 500–2,000 km. Autoscaled and then machine learning “cleaned” Digisonde NmF2 data indicate a 1.0 × 1011 el. m3 median positive bias in SAMI3 (equivalent to a 27% overestimation). The positive NmF2 bias is largest during the daytime, which may explain the relatively good performance in predicting HF links then. The underlying data sources and software used here are publicly available, so that interested groups may apply these tests to other models and time intervals.</p
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