Foster et al., 1982 - Google Patents
Electrostatic potential in the auroral ionosphere derived from Chatanika radar observationsFoster et al., 1982
View PDF- Document ID
- 9788626004370691989
- Author
- Foster J
- Banks P
- Doupnik J
- Publication year
- Publication venue
- Journal of Geophysical Research: Space Physics
External Links
Snippet
A technique is described for determining the latitudinal variation of the electrostatic potential associated with the ionospheric convection electric field. Using the north‐south electric field component derived from radar convection velocity experiments, the integral of E• dl is taken …
- 238000005421 electrostatic potential 0 title abstract description 5
Classifications
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01V—GEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS
- G01V1/00—Seismology; Seismic or acoustic prospecting or detecting
- G01V1/28—Processing seismic data, e.g. analysis, for interpretation, for correction
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Kamide et al. | Estimation of ionospheric electric fields, ionospheric currents, and field‐aligned currents from ground magnetic records | |
| Fejer | Low latitude electrodynamic plasma drifts: A review | |
| Friis‐Christensen et al. | Interplanetary magnetic field control of high‐latitude electric fields and currents determined from Greenland magnetometer data | |
| Iijima et al. | The relationship between interplanetary quantities and Birkeland current densities | |
| Pingree et al. | On the height variation of the equatorial F region vertical plasma drifts | |
| Kisabeth | On calculating magnetic and vector potential fields due to large‐scale magnetospheric current systems and induced currents in an infinitely conducting earth | |
| Foster et al. | Electrostatic potential in the auroral ionosphere derived from Chatanika radar observations | |
| She et al. | Global ionospheric electron density estimation based on multisource TEC data assimilation | |
| Yue et al. | Mapping the conjugate and corotating storm‐enhanced density during 17 March 2013 storm through data assimilation | |
| Gary et al. | Field‐aligned Poynting flux observations in the high‐latitude ionosphere | |
| Viljanen et al. | Climatology of rapid geomagnetic variations at high latitudes over two solar cycles | |
| Alcaydé et al. | Convection electric fields and electrostatic potential over 61°< Λ< 72° invariant latitude observed with the European Incoherent Scatter Facility: 1. Initial results | |
| Marsal et al. | Forcing the TIEGCM model with Birkeland currents from the active magnetosphere and planetary electrodynamics response experiment | |
| Zheng et al. | Ordered subsets-constrained ART algorithm for ionospheric tomography by combining VTEC data | |
| Jackson et al. | Three-dimensional tomography of interplanetary disturbances | |
| Kelly et al. | F‐region ionospheric structure associated with antisunward flow near the dayside polar cusp | |
| Weimer et al. | Satellite measurements through the center of a substorm surge | |
| Russell et al. | The fine-scale lunar magnetic field | |
| Park et al. | Vertical motions of the midlatitude F 2 layer during magnetospheric substorms | |
| Fontaine et al. | Numerical simulations of the magnetospheric convection including the effects of electron precipitation | |
| Yang et al. | New evidence of dayside plasma transportation over the polar cap to the prevailing dawn sector in the polar upper atmosphere for solar‐maximum winter | |
| Bust et al. | Ionospheric observations of the November 1993 storm | |
| Mazaudier | Electric currents above Saint‐Santin: 1. Data | |
| Kelley et al. | Simultaneous measurement of the horizontal components of the earth's electric field in the atmosphere and in the ionosphere | |
| Park et al. | The effects of magnetospheric convection on atmospheric electric fields in the polar cap |