New electron energy transfer rates for vibrational excitation of N&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt;

Павлов, А. В.

doi:10.1007/s00585-998-0176-9

Cited by 33 publications

(26 citation statements)

References 24 publications

(64 reference statements)

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“…These are from Stubbe and Varnum [2], Newton et al [3] and Pavlov [1,7]. These are from Stubbe and Varnum [2], Newton et al [3] and Pavlov [1,7].…”

Section: Calculation Of Electron Energy Transfer Ratesmentioning

confidence: 97%

“…Pavolv [1,7] gives a formula for an electron energy transfer rate Q 0ν (per molecule) for the transition 0 → ν:…”

Section: Calculation Of Electron Energy Transfer Ratesmentioning

confidence: 99%

“…Note that in practice we determine the electron energy transfer rate (Q) rather than the electron cooling rate (L), because L depends on quantities which are altitude dependent [1]. The electron temperature is, in turn, influenced by the interaction between electrons and neutral molecules, which play an important role in the cooling of electrons in the ionosphere.…”

Section: Electron Energy Transfer Rates In N 2 O 2 and Nomentioning

confidence: 99%

“…This code employs standard formulae [1,2,3] to calculate Q as a function of electron temperature T e , given the relevant electron-impact vibrational excitation cross sections. The first of these programs is rather limited in scope, being employed to specifically study electron energy transfer rates (Q) for vibrational excitation of molecules.…”

Section: Introductionmentioning

confidence: 99%

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Understanding the Role of Electron-driven Processes in Atmospheric Behaviour

Brunger¹

2004

AIP Conference Proceedings

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Electron-impact excitation plays a major role in emission from aurora and a less significant but nonetheless crucial role in the dayglow and nightglow. For some molecules, such as N 2 , O 2 and NO, electron-impact excitation can be followed by radiative cascade through many different sets of energy levels, producing emission with a large number of lines. We review the application of our statistical equilibrium program to predict this rich spectrum of radiation, and we compare results we have obtained against available independent measurements. In addition, we also review the calculation of energy transfer rates from electrons to N 2 , O 2 and NO in the thermosphere. Energy transfer from electrons to neutral gases and ions is one of the dominant electron cooling processes in the ionosphere, and the role of vibrationally excited N 2 and O 2 in this is particularly significant. The importance of the energy dependence and magnitude of the electron-impact vibrational cross sections in the calculation of these rates is assessed.

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“…These are from Stubbe and Varnum [2], Newton et al [3] and Pavlov [1,7]. These are from Stubbe and Varnum [2], Newton et al [3] and Pavlov [1,7].…”

Section: Calculation Of Electron Energy Transfer Ratesmentioning

confidence: 97%

“…Pavolv [1,7] gives a formula for an electron energy transfer rate Q 0ν (per molecule) for the transition 0 → ν:…”

Section: Calculation Of Electron Energy Transfer Ratesmentioning

confidence: 99%

Section: Electron Energy Transfer Rates In N 2 O 2 and Nomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Understanding the Role of Electron-driven Processes in Atmospheric Behaviour

Brunger¹

2004

AIP Conference Proceedings

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“…The reason why the authors' computation of T e is too large by 2 orders of magnitude is that the authors have neglected inelastic collisions with the neutrals. They use the elastic electron cooling rate, 2ν e ( T e − T n ) m e / m n , when they should use inelastic cooling rates, which are roughly 150 times larger [e.g., Gurevich , 1978; Schunk and Nagy , 2000, 1978; St.‐Maurice , 1990; Robinson , 1986; Dimant and Milikh , 2003; Pavlov , 1998a, 1998b]. For this reason, Lu et al [2005], [2005, equation (3)] yields T e values roughly 150 times larger than they should be.…”

Section: Ionospheric Electron Temperatures At High Latitudesmentioning

confidence: 99%

Comment on “Nonlinear electron heating by resonant shear Alfvén waves in the ionosphere” by J. Y. Lu et al.

St.-Maurice

2005

Geophysical Research Letters

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A comparison between resonant and nonresonant heating at EISCAT

et al. 2013

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[1] We compare the height-integrated electron heating rates from O-and X-mode HF pump waves to extract the components due to resonant and nonresonant heating mechanisms in the ionosphere. We present results from a November 2011 campaign in Norway, using the European Incoherent Scatter (EISCAT) heater facility and UHF radar. We show that the theoretical nonresonant, ohmic heating due to the electromagnetic pump wave electric field agrees with observations for X-mode pumping. For O-mode pumping, the observed height-integrated heating rate exceeds the theoretical ohmic electron heating rate by a factor of 2-5, the excess being attributed to resonant heating mechanisms. In addition, a persistent UHF ion-line enhancement is observed for O-mode and, more unusually, X-mode pumping. We attribute the latter to O-mode leakage in the X-mode pulse. For O-mode, we see a descent in altitude of the ion-line enhancement and show that this is most likely due to ionization from pump-induced fluxes of suprathermal electrons. We estimate the ionization rate and determine an enhanced electron flux showing that approximately 10-20% of the pump power is transferred to high energy suprathermal electrons.

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New electron energy transfer rates for vibrational excitation of N<sub>2</sub>

Cited by 33 publications

References 24 publications

Understanding the Role of Electron-driven Processes in Atmospheric Behaviour

Understanding the Role of Electron-driven Processes in Atmospheric Behaviour

Comment on “Nonlinear electron heating by resonant shear Alfvén waves in the ionosphere” by J. Y. Lu et al.

A comparison between resonant and nonresonant heating at EISCAT

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