2,456 research outputs found
Seasonal dependence of the longitudinal variations of nighttime ionospheric electron density and equivalent winds at southern midlatitudes
It has been indicated that the observed Weddell Sea anomaly (WSA) appeared to
be an extreme manifestation of the longitudinal variations in the Southern
Hemisphere, since the WSA is characterized by greater evening electron
density than the daytime density in the region near the Weddell Sea. In the
present study, the longitudinal variations of the nighttime F2-layer peak
electron density at southern midlatitudes are analyzed using the observations
of the Constellation Observing System for Meteorology, Ionosphere, and
Climate (COSMIC) satellites between 2006 and 2008. It is found that
significant longitudinal difference (> 150%) relative to
the minimum density at each local time prevails in all seasons, although the
WSA phenomenon is only evident in summer under this solar minimum condition.
Another interesting feature is that in summer, the maximum longitudinal
differences occur around midnight (~ 23:00–00:00 LT) rather than in
the evening (19:00–21:00 LT) in the evening, when the most prominent
electron density enhancement occurs for the WSA phenomenon. Thus the
seasonal–local time patterns of the electron density longitudinal variations
during nighttime at southern midlatitudes cannot be simply explained in terms
of the WSA. Meanwhile, the variations of the geomagnetic configuration and
the equivalent magnetic meridional winds/upward plasma drifts are analyzed to
explore their contributions to the longitudinal variations of the nighttime
electron density. The maximum longitudinal differences are associated with
the strongest wind-induced vertical plasma drifts after 21:00 LT in the
Western Hemisphere. Besides the magnetic declination–zonal wind effects, the
geographic meridional winds and the magnetic inclination also have
significant effects on the upward plasma drifts and the resultant electron
density
The Case Record of Ba-Yu-Quan Anchor Slab Retaining Wall
Anchor slab retaining wall is a kind of retaining structure, which consists of prefabricated rib-columns, panel slabs, tie-bars and anchor slabs embedded in earth fill. Since the structure was first used and developed in China in 1974, many such structure have been built on railways and other engineering projects. The reviewer of Second International Conference on Case Histories in Geotechnical Engineering gave a comments about this structure as follows: Chinese method anchor slab the construction should interest the western world . Ba-Yu-Quan anchor slab retaining wall has been instrumented to measure the load on the tie-bar, the horizontal displacement of the rib-columns, the horizontal earth pressure acting at the panel slabs, and the backfill settlement at different positions. This paper presents project description, construction of the project, data obtained from field observations and the comparison result with analysis and predicted values
A climatology of the F-layer equivalent winds derived from ionosonde measurements over two decades along the 120°-150°E sector
International audienceThe vertical equivalent winds (VEWs) at the F-layer are analyzed along the 120°-150°E longitude sector with an emphasis on their latitudinal dependence. The VEWs are derived from the monthly median data of fourteen ionosonde stations over two decades. The results show that the VEWs have considerable dependences on the magnetic latitude with an approximate symmetry about the magnetic equator. They are mostly controlled by the electric field drifts in the magnetic equatorial region, and shift to be mostly contributed by neutral winds at mid-latitudes. The relative contribution of the two dynamic factors is regulated by the magnetic dip in addition to their own magnitudes. The VEWs generally have opposite directions and different magnitudes between lower and higher latitudes. At solar minimum, the magnitudes of VEWs are only between -20 and 20m/s at lower latitudes, while at higher latitudes they tend to increase with latitudes, typically having magnitudes between 20-40m/s. At solar maximum, the VEWs are reduced by about 10-20m/s in magnitudes during some local times at higher latitudes. A tidal analysis reveals that the relative importance of major tidal components is also different between lower and higher latitudes. The VEWs also depend on local time, season and solar activity. At higher latitudes, the nighttime VEWs have larger magnitude during post-midnight hours and so do the daytime ones before midday. The VEWs tend to have an inverse relationship with solar activity not only at night, but also by day, which is different from the meridional winds predicted by the HWM93 model. The latitudinal dependence of VEWs has two prevailing trends: one is a maximum at the highest latitudes (as far as the latitudes concerned in the present work); the other is a mid-latitude maximum. These two latitudinal trends are mostly dependent on season, while they depend relatively weakly on local time and solar activity. The latitudinal gradients of VEWs also show a tendency of a mid-latitude maximum, except that there are much stronger latitudinal gradients at southern higher mid-latitudes in some seasons. The gradients during daytime are much smaller at solar maximum than minimum, whereas they are generally comparable at night under both solar activity levels
A new approach to the derivation of dynamic information from ionosonde measurements
International audienceA new approach is developed to derive dynamic information near the peak of the ionospheric F-layer from ionosonde measurements. This approach avoids deducing equivalent winds from the displacement of the observed peak height from a no-wind equilibrium height, so it need not determine the no-wind equilibrium height which may limit the accuracy of the deduced winds, as did the traditional servo theory. This approach is preliminarily validated with comparisons of deduced equivalent winds with the measurements from the Fabry-Perot interferometer, the Millstone Hill incoherent scatter radar and with previous works. Examples of vertical components of equivalent winds (VEWs), over Wuhan (114.4° E, 30.6° N, 45.2° dip), China in December 2000 are derived from Wuhan DGS-256 Digisonde data. The deduced VEWs show large day-to-day variations during the winter, even in low magnetic activity conditions. The diurnal pattern of average VEWs is more complicated than that predicted by the empirical Horizontal Wind Model (HWM). Using an empirical electric field model based on the observations from Jicamarca radar and satellites, we investigate the contributions to VEWs from neutral winds and from electric fields at the F-layer peak. If the electric field model is reasonable for Wuhan during this period, the neutral winds contribute mostly to the VEWs, and the contribution from the E × B drifts is insignificant
Coupling of Light and Mechanics in a Photonic Crystal Waveguide
Observations of thermally driven transverse vibration of a photonic crystal
waveguide (PCW) are reported. The PCW consists of two parallel nanobeams with a
240 nm vacuum gap between the beams. Models are developed and validated for the
transduction of beam motion to phase and amplitude modulation of a weak optical
probe propagating in a guided mode (GM) of the PCW for probe frequencies far
from and near to the dielectric band edge. Since our PCW has been designed for
near-field atom trapping, this research provides a foundation for evaluating
possible deleterious effects of thermal motion on optical atomic traps near the
surfaces of PCWs. Longer term goals are to achieve strong atom-mediated links
between individual phonons of vibration and single photons propagating in the
GMs of the PCW, thereby enabling opto-mechanics at the quantum level with
atoms, photons, and phonons. The experiments and models reported here provide a
basis for assessing such goals, including sensing mechanical motion at the
Standard Quantum Limit (SQL).Comment: 13 pages, 13 figure
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