Some new features of electron density irregularities over SHAR during strong spread F

Raizada, S.; Sinha, H. S. S.

doi:10.1007/s005850050015

Cited by 13 publications

(19 citation statements)

References 40 publications

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“…Vertical structures, in the scale size range of 5-10 km, are also quite prominent. The most intense irregularities occurred in three patches at 165-178 km, 210-257 km and 290-330 km [15,16]. Irregularities of a range of scale sizes starting from a few hundred meters to a few ten of kilometers are observed in this patch.…”

Section: Numerical Resultsmentioning

confidence: 82%

“…Irregularities of a range of scale sizes starting from a few hundred meters to a few ten of kilometers are observed in this patch. Studying the equatorial spread F irregularities using RH-560 rocket instrumented with Langmuir probes launched from SHAR it was established [15,16] that the relationship between the spectral index, p and the mean integrated spectral power (in 20 m to 200 m scale size range) could be represented by a Gaussian function.…”

Section: Numerical Resultsmentioning

confidence: 99%

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New Features of the ``Double-Humped Effect'' in the Magnetized Plasma

Jandieri¹,

Ishimaru²,

Kharshiladze³

2017

PIER M

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Abstract-Statistical moments of a scattered field are calculated in the first and second approximations using modified smooth perturbation method. Analytical expressions of both the variance and correlation function are obtained in the principle plane containing wave vector of an incident wave and external magnetic field. Observation points are spaced apart at small distances taking into account diffraction effects. Numerical calculations are carried out for the anisotropic Gaussian spectral function containing both anisotropic factor and the angle of inclination of elongated anisotropic plasma irregularities using the experimental data. It was shown that 3D surface of the correlation function of the phase fluctuation oscillate and these variations are decreased increasing characteristic spatial scale of plasma irregularities. New peculiarities of the "Double-humped Effect" are revealed in the collisionless magnetized plasma. It was shown that spatial scale and the inclination angle of elongated anisotropic plasma irregularities play important role in formation of a gap in the spatial power spectrum. Varying the magneto-ionospheric plasma parameters and values of characteristic spatial scales of anisotropic irregularities the depth of a dip increases and oscillates.

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Section: Numerical Resultsmentioning

confidence: 82%

Section: Numerical Resultsmentioning

confidence: 99%

New Features of the ``Double-Humped Effect'' in the Magnetized Plasma

Jandieri¹,

Ishimaru²,

Kharshiladze³

2017

PIER M

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“…The incident electromagnetic wave has the frequency of 3 MHz ( [15] that the intermediate range irregularities (100 m -2 km) were observed in abundance in altitude regions 220-250 km and 290-320 km. Irregularities of a range of scale sizes starting from a few hundred meters to a few ten of kilometers are observed in these patches.…”

Section: Numerical Calculationsmentioning

confidence: 99%

Power Spectra of Ionospheric Scintillations

Jandieri

Ishimaru

Rawat

et al. 2017

AEM

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Second order statistical moments of the phase fluctuations are obtained taking into account the boundary condition, diffraction effects and polarization coefficients of the ordinary and extraordinary waves. The variance and the correlation function are calculated for arbitrary 3D spectral function of electron density fluctuations containing both anisotropic Gaussian and power-law spectra; anisotropy coefficient and the orientation angle of elongated plasma irregularities. The phase scintillation index and the scintillation level are analyzed numerically. Maximum of the scintillation index for small-scale irregularities is in the interval 0.2-0.3 corresponding to the moderate scintillation intensity, within the weak-scatter regime. Splashes are revealed for different anisotropy factor of elongated largescale irregularities varying orientation angle with respect to the lines of force of geomagnetic field. Scintillation index is calculated for small-scale irregularities using the "frozenin" assumption and taking into account movement of rigid irregularities. Log-log plots of the power spectrum of the intensity fluctuations have the same minimums satisfying the "standard relationship" of scattered ordinary and extraordinary waves. It was shown that the normalized scintillation level growth in both non-fully-developed diffraction pattern and in transition zone increasing anisotropy factor. Rising orientation angle scintillation level decreases and splashes arises in fully developed scintillation region.

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“…Prakash and Pal (1985) found (a) vertical scales up to 25 km wavelength in 100-140 km region and explained these in terms of wind shear mechanism, (b) vertical scales up to 100 km wavelength whose mechanism of generation was not clear (c) large variation in the height of the base F region, which was explained in terms of variation of downward drift velocity of plasma and (d) the presence of plasma depletions above 275 km where the electron density was depleted by factors as large as 15. Sinha et al (1999) and Raizada and Sinha (2000) used a cylindrical LP sensor along with LP double probes for electric field measurement along and across the spin axis of a RH 300 MK II rocket during a strong spread F event. Electron density irregularities in 30-300 m scale size range were observed in the F region valley over SHAR, a region which was earlier believed to be free from irregularities.…”

Section: Equatorial Spread F Irregularitiesmentioning

confidence: 99%

“…LP was also used to study irregularities during a number of spread F events by Prakash and Pal (1985), and Raizada and Sinha (2000) from Sriharikota. Prakash and Pal (1985) found (a) vertical scales up to 25 km wavelength in 100-140 km region and explained these in terms of wind shear mechanism, (b) vertical scales up to 100 km wavelength whose mechanism of generation was not clear (c) large variation in the height of the base F region, which was explained in terms of variation of downward drift velocity of plasma and (d) the presence of plasma depletions above 275 km where the electron density was depleted by factors as large as 15.…”

Section: Equatorial Spread F Irregularitiesmentioning

confidence: 99%

Rocket-borne Langmuir probe for plasma density irregularities

Sinha¹

2013

An Introduction to Space Instrumentation

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Ionospheric plasma density exhibits very large spatial and temporal variations known as ionosphere irregularities. These irregularities are generated by a number of processes related to plasma as well as neutral dynamics. The rocket-or satellite-borne Langmuir probe (LP) is very simple and yet a very powerful tool to measure spatial variation of plasma density enabling one to study ionosphere irregularities. This article describes how a rocket-borne LP can be used to study ionosphere irregularities. It begins with the basic principle of the LP, the ionospheric regions where it can be used, various sizes and shapes of the LP sensors, the effect of geomagnetic field and vehicle wake on LP measurements. Mechanical and electronic details of typical LP instrument are given next. Strengths, weaknesses and specifications of LP instrument are also given. Rocket-borne LP has been used by a large number of scientists in the world to study ionospheric irregularities produced through plasma instabilities in the equatorial electrojet region, in spread F and those produced by neutral turbulence. Highlights of such irregularity measurements are presented to give the reader a flavor of the type of studies which can be undertaken using a rocket-borne LP. The present capability of rocket-borne LP is to detect vertical scale sizes of ionospheric irregularities from a few km down to about 10 cm with percentage amplitudes as small as 0.001%. Finally, a few suggestions are given for the improvement the LP instrumentation for future use. Key words: Langmuir probe, plasma density irregularities, in situ measurement. Rocket-borne Langmuir Probe for Plasma IrregularitiesThe Langmuir probe (LP) is used on rockets to determine the amplitude and spectra of electron density irregularities over a large vertical scale-size range, typically lying between a few km down to about 10 cm. Plasma irregularities have been studied at all latitudes, especially so around geomagnetic equator, due to special geometry of geomagnetic field lines which are horizontal. Horizontal magnetic field along with vertically upward (downward) Hall polarization electric field during the day (night), is the major destabilizing forcing for the excitation of a range of plasma instabilities at altitudes higher than about 85 km. Neutral turbulence produces fluctuations in neutral density, at altitudes below about 100 km, which can be transferred to electron density, due to high neutral-ion collision frequencies at such altitudes and the charge neutrality of plasma. Although gross features of various plasma instabilities and neutral forcings producing these irregularities are understood, there are many aspects which still defy a suitable explanation, such as why equatorial spread F irregularities are present on some nights and absent on other nights. It is, therefore, essential that the parameters of irregularities such as amplitudes, scale sizes and spectrum be measured along with other complementary parameters such as electric fields, electric currents, composition, neutral...

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Some new features of electron density irregularities over SHAR during strong spread F

Cited by 13 publications

References 40 publications

New Features of the ``Double-Humped Effect'' in the Magnetized Plasma

New Features of the ``Double-Humped Effect'' in the Magnetized Plasma

Power Spectra of Ionospheric Scintillations

Rocket-borne Langmuir probe for plasma density irregularities

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