Group travel time for proton whistlers in the ionosphere

Singh, S. N.; Tolpadi, S. K.

doi:10.1029/ja080i004p00694

Cited by 6 publications

(3 citation statements)

References 9 publications

(5 reference statements)

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“…In this case, the mathematical analysis is very complicated and a WKB method must be used (Budden 1961;Khan & Paul 1977). Consideration of thermal effects (Singh & Tolpadi 1975;Singh, Tiwari & Tolpadi 1976) and the streaming velocity of the plasma species, including newly formed ions (Das & Sur 1986), is also likely to lead to interesting results regarding nonlinear effects in whistlers.…”

Section: Some Concluding Remarksmentioning

confidence: 99%

Wavenumber shift of an obliquely propagating ion-cyclotron whistler

1989

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Section: Some Concluding Remarksmentioning

confidence: 99%

Wavenumber shift of an obliquely propagating ion-cyclotron whistler

1989

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“…The propagation of ion-cyclotron whistlers has been extensively studied since Smith et al [ 1964] first observed the proton whistlers recorded in the VLF receivers aboard the Alouette 1 and lnjun 3 satellites [Gurnett et al, 1965;Barrington et al, 1966;Gurnett and Rodriguez, 1970;Smith, 1970;Rodriguez and Gurnett, 1971;Wang, 1971;Chan et al, 1972;Jones, 1969Jones, , 1972Fijalkow et al, 1973]. The observed characteristic features of proton whistlers have been used by a number of workers to estimate some of the parameters in the ionosphere [Gurnett et al, 1965;Shawhah and Gurnett, 1966;Gurnett and Shawhah, 1966;Gurnett and Brice, 1966;Lucas and Brice, 1971].…”

Section: Introductionmentioning

confidence: 99%

“…All these theoretical studies are based on the theory of the propagation of electromagnetic waves in a cold multicomponent magnetoplasma developed by Smith and Brice [1964] and Gurnett et al [1965]. Singh and Tolpadi [1975] Because of their thermal motion some protons will absorb energy from the wave by cyclotron damping if the Doppler-shifted wave frequency is equal to their gyrofrequency. The rate at which wave energy is absorbed depends upon the number of protons that see the wave at their gyrofrequenCy.…”

Section: Introductionmentioning

confidence: 99%

Characteristics of electron-ion whistlers and their application to ionospheric probing

Singh¹,

Tiwari²,

Tolpadi³

1976

J. Geophys. Res.

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In this communication the effect of ion temperature on the propagation of electron‐ion whistlers in the ionosphere is investigated. A general expression including the effect of ion temperature is derived for the group travel time for the electron‐ion whistler as it travels from the base of the ionosphere to the satellite. A study of the dependence of the group travel time on ion temperature indicates that thermal effects contribute about 20% to the total group travel time for the proton whistlers. Further, from the expression for the group travel time including the effect of the ion temperature in conjunction with the generalized dispersion relation a relation for the cyclotron damping rate (both temporal and spatial) has been obtained. A detailed study of the cyclotron damping rate with travel time and ion temperature leads to the conclusion that the observed amplitude cutoff characteristics for the proton whistler can be explained on the basis of the mechanism of cyclotron damping. It is also shown that the knowledge of the group travel time of an electron‐ion whistler can be used to estimate the ion temperature at the satellite.

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