J. K. Alexander’s research while affiliated with Louisiana State University at Alexandria and other places

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Publications (25)


Voyager observations of Jovian millisecond radio bursts
  • Article

June 1984

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11 Reads

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22 Citations

Journal of Geophysical Research Atmospheres

J. K. Alexander

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M. D. Desch

Voyager Planetary Radio Astronomy data collected over 30-day intervals centered on the two close encounters with Jupiter were utilized to study the characteristics of millisecond-duration radio bursts (s-bursts) at frequencies between 5 and 15 MHz. In this frequency range, s-bursts are found to occur almost independently of Central Meridian Longitude and to depend entirely on the phase of Io with respect to the observer's planetocentric line of sight. Individual bursts typically cover a total frequency range of about 1.5 to 3 MHz, and they are usually strongly circularly polarized. Most bursts in a particular s-burst storm will exhibit the same polarization sense (either right-hand or left-hand), and there is some evidence for a systematic pattern in which one polarizations sense is preferred over the other as a function of Io phase and Central Meridian Longitude. These data are all suggestive of a radio source that is located along the instantaneous Io flux tube and that extends over a linear dimension of 5000 km along the field lines in both the Northern and Southern Hemispheres. Previously announced in STAR as N84-17109


Phenomenology of magnetospheric radio emissions

February 1983

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20 Reads

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223 Citations

Jupiter has now been observed over 24 octaves of the radio spectrum, from about 0.01 MHz to 300,000 MHz. Its radio emissions fill the entire spectral region where interplanetary electromagnetic propagation is possible at wavelengths longer than infrared. Three distinct types of radiation are responsible for this radio spectrum. Thermal emission from the atmosphere accounts for virtually all the radiation at the high frequency end. Synchrotron emission from the trapped high-energy particle belt deep within the inner magnetosphere is the dominant spectral component from about 4000 to 40 MHz. The third class of radiation consists of several distinct components of sporadic low frequency emission below 40 MHz. The decimeter wavelength emission is considered, taking into account the discovery of synchrotron emission, radiation by high-energy electrons in a magnetic field, and the present status of Jovian synchrotron phenomenology. Attention is also given to the decameter and hectometer wavelength emission, and emissions at kilometric wavelengths.


Phenomenology of magnetospheric radio emissions

January 1983

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6 Reads

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200 Citations

Jupiter's magnetosphere (the region of space in which Jupiter's magnetic field influences the motion of charged particles) is the largest object in the solar system; it exhibits new phenomena and behaves, in some respects, like a pulsar. It is a magnetosphere whose physics is dominated by internal sources of plasma and energy. This book consists of twelve carefully interwoven articles written by leading space scientists who summarize our state of knowledge of the physics of the magnetosphere surrounding the planet Jupiter. Ground-based data as well as information from the Pioneer and Voyager spacecraft are used in developing both physical descriptions and theoretical understanding. Physics of the Jovian Magnetosphere is a valuable reference work for those doing research in magnetospheric physics and in a number of related disciplines.


Planetary Radio Astronomy Observations from Voyager 2 Near Saturn

February 1982

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7 Reads

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109 Citations

Science

J W Warwick

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D R Evans

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J H Romig

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[...]

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B M Pedersen

Planetary radio astronomy measurements obtained by Voyager 2 near Saturn have added further evidence that Saturnian kilometric radiation is emitted by a strong dayside source at auroral latitudes in the northern hemisphere and by a weaker source at complementary latitudes in the southern hemisphere. These emissions are variable because of Saturn's rotation and, on longer time scales, probably because of influences of the solar wind and Dione. The electrostatic discharge bursts first discovered by Voyager 1 and attributed to emissions from the B ring were again observed with the same broadband spectral properties and an episodic recurrence period of about 10 hours, but their occurrence frequency was only about 30 percent of that detected by Voyager 1. While crossing the ring plane at a distance of 2.88 Saturn radii, the spacecraft detected an intense noise event extending to above 1 megahertz and lasting about 150 seconds. The event is interpreted to be a consequence of the impact, vaporization, and ionization of charged, micrometer-size G ring particles distributed over a vertical thickness of about 1500 kilometers.


Planetary radio astronomy observations from Voyager2 near Saturn

December 1981

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16 Reads

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27 Citations

Voyager-2 planetry radio astronomy measurements obtained near Saturn are discussed. They indicate that Saturnian kilometric radiation is emitted by a strong, dayside source at auroral latitudes in the northern hemisphere and by a weaker (by more than an order of magnitude) source at complementary latitudes in the southern hemisphere. These emissions are variable both due to Saturn's rotation and, on longer time scales, probably due to influences of the solar wind and the satellite Dione. The Saturn electrostatic discharge bursts first discovered by Voyager-1 and attributed to emissions from the B-ring were again observed with the same broadband spectral properties and a 10(h)11(m) + or - 5(m) episodic recurrence period but with an occurrence frequency of only of about 30 percent of that detected with Voyager-1. During the crossing of the ring plane at a distance of 2.88 RS, an intense noise event is interpreted to be consequence of the impact/vaporization/ionization of charged micron-size G-ring particles distributed over a total vertical thickness of about 1500 km.


Radio Jupiter after Voyager - An overview of the planetary radio astronomy observations

October 1981

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10 Reads

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77 Citations

Journal of Geophysical Research Atmospheres

An overview of Jupiter's low-frequency radio emission morphology as observed by the planetary radio astronomy (PRA) instrument onboard the Voyager spacecraft is presented. The PRA measurement capabilities and limitations are summarized, based on over two years of experience with the instrument. As a direct consequence of the PRA spacecraft observations, unprecedented in terms of their sensitivity and frequency coverage, at least three previously-unrecognized emission components have been discovered: broadband and narrow-band kilometric emission, and the lesser-arc decametric emission. Their properties are reviewed. In addition, the fundamental structure of the decameter wavelength and hectometer wavelength emission, now believed to be almost exclusively in the form of complex but repeating arc structures in the frequencytime domain, is described. Dramatic changes in the emission morphology of some components as a function of the sun-Jupiter-spacecraft angle (local time) are described. Finally, the PRA in situ measurements of the Io plasma torus hot-to-cold electron density and temperature ratios are summarized.


Synoptic observations of Jupiter's radio emissions - Average statistical properties observed by Voyager

October 1981

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16 Reads

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64 Citations

Journal of Geophysical Research Atmospheres

Observations of Jupiter's low-frequency radio emissions collected over one-month intervals before and after each Voyager encounter are analyzed to provide a synoptic view of the average statistical properties of the emissions. Compilations of occurrence probability, average power flux density, and average sense of circular polarization are given as a function of central meridian longitude, phase of Io, and frequency. The results are then compared with ground-based observations. The necessary geometric conditions and preferred polarization sense for Io-related decametric emission observed by Voyager from above both the dayside and nightside hemispheres are found to be basically the same as those observed in earth-based studies.


Observations of electron gyroharmonic waves and the structure of the Io torus

September 1981

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7 Reads

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87 Citations

Journal of Geophysical Research Atmospheres

Narrow-banded emission were observed by the planetary radio astronomy experiment on the Voyager 1 spacecraft as it traversed the Io plasma torus. These waves occur between harmonics of the electron gyrofrequency and are the Jovian analogue of electrostatic emissions observed and theoretically studied for the terrestrial magnetosphere. The observed frequencies always include the component near f/sub uhr'/ the upper hydbrid resonant frequency, but the distribution of the other observed emissions varies in a systematic way with position in the torus. A detailed discussion of the observations is presented. A refined model of the electron density variation, based on identification of the f/sub uhr/ line, is also included. Spectra of the observed waves are analyzed in terms of the linear instability of an electron distribution function consisting of isotropic cold electrons and hot loss cone electrons. The positioning of the observed auxiliary harmonics with respect to f/sub uhr/ is shown to be an indicator of the cold to hot temperature ratio T/sub C//T/sub H/. It is concluded that this ratio increases systematically by an overall factor of perhaps 4 or 5 between the inner (Lapprox.5 R/sub J/) and outer (Lapprox.9 R/sub J/) portions of the torus. Other relevant plasma and spectroscopic data are discussed.



Planetary Radio Astronomy Observations from Voyager 1 Near Saturn

May 1981

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25 Reads

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236 Citations

Science

The Voyager 1 planetary radio astronomy experiment detected two distinct kinds of radio emissions from Saturn. The first, Saturn kilometric radiation, is strongly polarized, bursty, tightly correlated with Saturn's rotation, and exhibits complex dynamic spectral features somewhat reminiscent of those in Jupiter's radio emission. It appears in radio frequencies below about 1.2 megahertz. The second kind of radio emission, Saturn electrostatic discharge, is unpolarized, extremely impulsive, loosely correlated with Saturn's rotation, and very broadband, appearing throughout the observing range of the experiment (20.4 kilohertz to 40.2 megahertz). Its sources appear to lie in the planetary rings.


Citations (17)


... Relativistic electrons trapped in radiation belts experience deflection due to the planet's magnetic field and subsequently emit synchrotron radiation. To date, only the radiation belts of Jupiter have been confirmed to exhibit this phenomenon in the solar system (Carr et al., 1983;de Pater, 1981;Grießmeier et al., 2011;Girard et al., 2016 and references therein). These observations have significantly contributed to our comprehension of the dynamics of energetic electrons close to Jupiter (Nénon et al., 2017;Santos-Costa et al., 2008;Sicard et al., 2004). ...

Reference:

A New Cyclo‐Synchrotron Model for Lunar‐Based Observations of Earth's Radiation Belts
Phenomenology of magnetospheric radio emissions
  • Citing Chapter
  • January 1983

... Specifically, the SKR generated in the northern hemisphere is right-handed whilst the SKR generated in the southern hemisphere is left-handed [Warwick et al., 1982]. SKR can also be produced on the O-mode (a linearly polarize ) with purely left-handed (LH) polarization (L-O), although the R-X mode emissions are more intense. ...

Planetary radio astronomy observations from Voyager2 near Saturn
  • Citing Article
  • December 1981

... A common way to determine the electron density is by locating the upper hybrid resonance frequency, either by observing thermally excited electrostatic emission or upper hybrid waves from plasma instabilities, both of which are very common features in planetary magnetospheres (Birmingham et al., 1981;Gurnett et al., 1981Gurnett et al., , 1996Gurnett et al., , 1998Gurnett et al., , 2001Kurth et al., 1979Kurth et al., , 1980Kurth et al., , 2015Menietti et al., 2005;Mosier et al., 1973;Shaw & Gurnett, 1975;Warwick et al., 1979;). However, due to the unique plasma environment of the Jovian high-latitude regions close to the planet (i.e., the electron cyclotron frequency, ce f , is much larger than the electron plasma frequency, pe f , with / pe ce f f ranging from ∼6 × 10 −4 to ∼4 × 10 −2 ), the upper hybrid resonance frequency is often equal to, or nearly equal to, the electron cyclotron frequency. ...

Observations of electron gyroharmonic waves and the structure of the Io torus
  • Citing Article
  • September 1981

Journal of Geophysical Research Atmospheres

... The visibility of AKR is a strong function of the position of the observer. AKR and its source regions are mostly concentrated at nightside local times (LTs); AKR has been observed consistently from LTs between  E 1600-0300 hr, whereas the most intense source regions are located at 2100-2200 LT (e.g., Alexander & Kaiser, 1976;Gurnett, 1974;Panchenko, 2003). The visibility of AKR to a spacecraft at various latitudes is constrained by the beaming of the emission, as mentioned above. ...

Terrestrial kilometric radiation. I - Spatial structure studies
  • Citing Article
  • January 1977

Journal of Geophysical Research Atmospheres

... We note that in addition to the spacecraft in Tab. 1 some other satellites occasionally reported observations of AKR from remote and closer in (among them were ISIS 1 (Benson et al., 1979), POLAR (Menietti et al., 2000;Mogilevsky et al., 2008)), ISEE 3 (Benson et al., 1991;Gallagher & Gurnett, 1979;Imhof et al., 2000;Hashimoto et al., 2016;Grach et al., 2020;Green et al., 2004).) Galileo (Menietti et al., 1996), ERG (Kolpak et al., 2021), (Gurnett, 1974) Voyager 1& 2 waves/plasma (Kaiser et al., 1978) AMPTE IRM ±(15 − 18) waves/plasma (LaBelle et al., 1989) Geotail −(10 − 30) PWI/LEP (Nishida, 1994;Kokubun et al., 1994) (Mukai et al., 1994;Matsumoto et al., 1994a, b) CLUSTER > | ± 10| PWI/plasma (Mutel et al., 2003;Balogh et al., 1997) (Yearby & Pickett, 2022) STEREO waves (Panchenko et al., 2009) MMS ∼ −20 PWI/plasma (Burch et al., 2016;Torbert et al., 2016) Cassini 1.2 to −6400 PWI (Anderson et al., 2005;Lamy et al., 2010) Wind < | ± 300| waves/plasma (Bougeret et al., 1995;Lepping et al., 1995) (Wilson III et al., 2021) DE 1 < 5 PWI/plasma (Mellott et al., 1986;Hoffman et al., 1981) (Mellott et al., 1984) Hawkeye < 3 plasma (Green et al., 1977;Voots et al., 1977) Fast < 2 PWI/plasma (Carlson et al., 1998, a;Pfaff et al., 1998) Viking < 3 PWI/plasma (Hultqvist, 1990;Ungstrup et al., 1990) (Bahnsen et al., 1989;Roux et al., 1993) Freja < 2 PWI (Wahlund et al., 1994;Louarn et al., 1994) S3-3 < 2.5 PWI/plasma (Mozer et al., 1977;Temerin et al., 1981) (Temerin, 1984) PWI = Plasma Wave Instrumentation, LEP = Low Energy Particles waves = plasma waves, plasma = general plasma measurements Exos-B (Morioka et al., 1981), Interball (Parrot et al., 2001;Mironov et al., 2006;Mogilevsky et al., 2005Mogilevsky et al., , 2011Moiseenko et al., 2013), From a more fundamental physics point of view spacecraft crossing the auroral region provided invaluable information about the presumable AKR source region. Not only that they confirmed the generation of AKR in the upper auroral ionosphere/lower magnetosphere mainly on the nightside and below the cusp on the dayside (Frey et al., 2019). ...

Correction [to “Direct measurements by Voyagers 1 and 2 of the polarization of terrestrial kilometric radiation”]
  • Citing Article
  • November 1978

... The aforementioned correlation of AKR with geomagnetic disturbances is particularly highlighted during substorms. This is quantified in studies of the AKR power and the auroral electrojet (AE) index (Kaiser & Alexander, 1977;Voots et al., 1977), field-aligned currents (Green et al., 1982) and electron precipitation (Imhof et al., 2000). Global observations of the auroral oval at substorm onset have also provided an insight to coincident AKR enhancement (Liou et al., 2000). ...

Relationship between auroral substorms and the occurrence of terrestrial kilometric radiation
  • Citing Article
  • December 1977

Journal of Geophysical Research Atmospheres

... cWAVE is an electromagnetic waves instrument for the study of terrestrial AKR (auroral kilometric radiation) emissions, occurring in the auroral region. It would then take advantage of the Moon occultation method, which was first implemented by the Radio Astronomy Explorer-2 mission (Kaiser and Alexander, 1976). An additional objective is the study of the radio emissions emitted by accelerated particles in the solar corona and the solar wind. ...

Source location measurements of terrestrial kilometric radiation obtained from lunar orbit
  • Citing Article
  • February 1976

... Jovian S-bursts were first observed by Carr et al. (1958) as a unique type of decametric radiation. They have been observed many times since then by ground-based receivers (Riihimaa 1991; Zarka 2004; Ryabov et al. 2007) and by spacecraft-borne receivers (Desch & Carr 1974;Alexander & Desch 1984). These emissions consist of frequencies ranging from ∼10 to ∼40 MHz. ...

Voyager observations of Jovian millisecond radio bursts
  • Citing Article
  • June 1984

Journal of Geophysical Research Atmospheres

... [11] Recently, Imai et al. [2008], using all the data during Cassini flyby, first recognized the "V-shape" pattern within non-Io-DAM, which was originally suggested by Thieman and Smith [1978] and Alexander et al. [1981], in the frequency versus longitude plot between 9 MHz and 16 MHz. Moreover, there are two enhanced peaks at 160°and 240°CML at 16 MHz. ...

Synoptic observations of Jupiter's radio emissions - Average statistical properties observed by Voyager
  • Citing Article
  • October 1981

Journal of Geophysical Research Atmospheres

... These experiments were based on simultaneous observations from the Earth (Nançay) and from a Soviet space probe (Mars-3 for STEREO-1 and Mars-7 for STEREO-5). Shortly afterwards, Nançay was officially associated with NASA's Voyager mission, a spare model of the flight radio astronomy instrument (PRA) being fed by the Nançay Decameter Array at the times of the Jupiter encounters (Boischot et al., 1981). ...

Radio Jupiter after Voyager - An overview of the planetary radio astronomy observations
  • Citing Article
  • October 1981

Journal of Geophysical Research Atmospheres