dor_id: 4133032

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590.#.#.d: Los artículos enviados a la revista "Geofísica Internacional", se juzgan por medio de un proceso de revisión por pares

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650.#.4.x: Físico Matemáticas y Ciencias de la Tierra

336.#.#.b: article

336.#.#.3: Artículo de Investigación

336.#.#.a: Artículo

351.#.#.6: http://revistagi.geofisica.unam.mx/index.php/RGI

351.#.#.b: Geofísica Internacional

351.#.#.a: Artículos

harvesting_group: RevistasUNAM

270.1.#.p: Revistas UNAM. Dirección General de Publicaciones y Fomento Editorial, UNAM en revistas@unam.mx

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270.#.#.d: MX

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883.#.#.a: Revistas UNAM

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856.4.0.u: http://revistagi.geofisica.unam.mx/index.php/RGI/article/view/1229/1205

100.1.#.a: Dessler, A. J.

524.#.#.a: Dessler, A. J. (1991). Planetary magnetospheres. Geofísica Internacional; Vol. 30 Núm. 4: Octubre 1, 1991; 213-218. Recuperado de https://repositorio.unam.mx/contenidos/4133032

245.1.0.a: Planetary magnetospheres

502.#.#.c: Universidad Nacional Autónoma de México

561.1.#.a: Instituto de Geofísica, UNAM

264.#.0.c: 1991

264.#.1.c: 1991-10-01

653.#.#.a: Magnetosferas; Jupiter; Interacción con el viento solar; Magnetospheres; Jupiter; Solar wind interaction

506.1.#.a: La titularidad de los derechos patrimoniales de esta obra pertenece a las instituciones editoras. Su uso se rige por una licencia Creative Commons BY-NC-ND 4.0 Internacional, https://creativecommons.org/licenses/by-nc-nd/4.0/legalcode.es, para un uso diferente consultar al responsable jurídico del repositorio por medio del correo electrónico revistagi@igeofisica.unam.mx

884.#.#.k: http://revistagi.geofisica.unam.mx/index.php/RGI/article/view/1229

001.#.#.#: 063.oai:revistagi.geofisica.unam.mx:article/1229

041.#.7.h: spa

520.3.#.a: The Pioneer, Mariner and Voyager spacecraft have presented us with a bewildering variety of planetary magnetospheres. The Earth"s magnetosphere, because of its proximity, is the best understood. The solar wind supplies some plasma and, most important, the power to drive the wide range of phenomena observed in the Earth"s magnetosphere. For Earth, the ionosphere is the primary source of magnetospheric plasma. In contrast, the plasma in Jupiter"s magnetosphere is largely derived from volcanic gases that escape from its satellite Io (and secondarily from the Jovian ionosphere), and the power for Jupiter"s magnetosphere is supplied by the kinetic energy of Jupiter"s spin. Thus, the solar wind is not an important source of plasma or energy for Jupiter. Jupiter"s magnetosphere demonstrates complex patterns of behavior. For example, Jovian magnetospheric phenomena are, in general, not axially symmetric. Nearly all are organized so that they occur within a single -160° range of longitude known as "the active sector". Differences and similarities in what has turned out to be a virtual zoo of magnetospheres test our basic understanding of magnetospheric processes and lead us to develop new, more general principles of magnetospheric physics. Jupiter"s magnetosphere, being the most dynamic and having the least in common with other solar system magnetospheres, is perhaps the most interesting of the variety now available for comparative study.

773.1.#.t: Geofísica Internacional; Vol. 30 Núm. 4: Octubre 1, 1991; 213-218

773.1.#.o: http://revistagi.geofisica.unam.mx/index.php/RGI

022.#.#.a: ISSN-L: 2954-436X; ISSN impreso: 0016-7169

310.#.#.a: Trimestral

300.#.#.a: Páginas: 213-218

264.#.1.b: Instituto de Geofísica, UNAM

doi: https://doi.org/10.22201/igeof.00167169p.1991.30.4.1229

handle: 712f9e285f5a0afd

harvesting_date: 2023-06-20 16:00:00.0

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file_creation_date: 2022-07-05 10:52:48.0

file_modification_date: 2022-07-24 01:42:47.0

file_creator: A.J. Dessler

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245.1.0.b: Planetary magnetospheres

last_modified: 2023-06-20 16:00:00

license_url: https://creativecommons.org/licenses/by-nc-nd/4.0/legalcode.es

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Artículo

Planetary magnetospheres

Dessler, A. J.

Instituto de Geofísica, UNAM, publicado en Geofísica Internacional, y cosechado de Revistas UNAM

Licencia de uso

Procedencia del contenido

Entidad o dependencia
Instituto de Geofísica, UNAM
Revista
Geofísica Internacional
Repositorio
Revistas UNAM
Contacto
Revistas UNAM. Dirección General de Publicaciones y Fomento Editorial, UNAM en revistas@unam.mx

Cita

Dessler, A. J. (1991). Planetary magnetospheres. Geofísica Internacional; Vol. 30 Núm. 4: Octubre 1, 1991; 213-218. Recuperado de https://repositorio.unam.mx/contenidos/4133032

Descripción del recurso

Autor(es)
Dessler, A. J.
Tipo
Artículo de Investigación
Área del conocimiento
Físico Matemáticas y Ciencias de la Tierra
Título
Planetary magnetospheres
Fecha
1991-10-01
Resumen
The Pioneer, Mariner and Voyager spacecraft have presented us with a bewildering variety of planetary magnetospheres. The Earth"s magnetosphere, because of its proximity, is the best understood. The solar wind supplies some plasma and, most important, the power to drive the wide range of phenomena observed in the Earth"s magnetosphere. For Earth, the ionosphere is the primary source of magnetospheric plasma. In contrast, the plasma in Jupiter"s magnetosphere is largely derived from volcanic gases that escape from its satellite Io (and secondarily from the Jovian ionosphere), and the power for Jupiter"s magnetosphere is supplied by the kinetic energy of Jupiter"s spin. Thus, the solar wind is not an important source of plasma or energy for Jupiter. Jupiter"s magnetosphere demonstrates complex patterns of behavior. For example, Jovian magnetospheric phenomena are, in general, not axially symmetric. Nearly all are organized so that they occur within a single -160° range of longitude known as "the active sector". Differences and similarities in what has turned out to be a virtual zoo of magnetospheres test our basic understanding of magnetospheric processes and lead us to develop new, more general principles of magnetospheric physics. Jupiter"s magnetosphere, being the most dynamic and having the least in common with other solar system magnetospheres, is perhaps the most interesting of the variety now available for comparative study.
Tema
Magnetosferas; Jupiter; Interacción con el viento solar; Magnetospheres; Jupiter; Solar wind interaction
Idioma
spa
ISSN
ISSN-L: 2954-436X; ISSN impreso: 0016-7169

Enlaces