An improved algorithm for determining neutral winds from the height of the F₂ peak electron density

Abstract: One of the greatest uncertainties in modeling the ionospheric densities and temperatures lies in the neutral winds that affect the vertical ion drift. Wind measurements are difficult to make, and current wind models are not adequate. An alternative is to deduce an equivalent meridlonal neutral wind from measurements of the height of the F2 peak electron density. This method has been effective in allowing ionospheric modelers to reproduce the observed height with reasonable precision when the peak height does n… Show more

“…(A13 , A14) given by Pavlov (1994). The large uncertainities in the calculated h lead to large errors in the modeled electron densities and peak height altitude, hmF2, of the F2-layer (Richards, 1991;Pavlov, 1994). This problem was largely overcome when Richards (1991) developed a technique for deriving equivalent neutral winds from the observed hmF2.…”

“…The large uncertainities in the calculated h lead to large errors in the modeled electron densities and peak height altitude, hmF2, of the F2-layer (Richards, 1991;Pavlov, 1994). This problem was largely overcome when Richards (1991) developed a technique for deriving equivalent neutral winds from the observed hmF2. Ideally, the observed hmF2 should be available for several hours before the time of the comparison, but very often only a limited set of hmF2 measurements is available or we have not got the observed hmF2 and thus cannot use the method developed by Richards (1991) or our modi®cation of this method (Pavlov and Buonsanto, 1997) to calculate an equivalent plasma drift velocity.…”

“…This problem was largely overcome when Richards (1991) developed a technique for deriving equivalent neutral winds from the observed hmF2. Ideally, the observed hmF2 should be available for several hours before the time of the comparison, but very often only a limited set of hmF2 measurements is available or we have not got the observed hmF2 and thus cannot use the method developed by Richards (1991) or our modi®cation of this method (Pavlov and Buonsanto, 1997) to calculate an equivalent plasma drift velocity. To overcome this problem, we can try to use hmF2 IRI given by the IRI-90 model (Bilitza, 1990) to calculate an equivalent plasma drift velocity, IRI , for some hypothetical undisturbed conditions with the same solar and time conditions as during the studied conditions:…”

“…In this study we employ model A and compare results with those from models B and C to evaluate the e ects of the uncertainties in these rate coe cients on calculated integral airglow intensities at 630 nm in the SAR-arc regions. We have no information on hmF2 and thus can use neither the method developed by Richards (1991) nor our modi®-cation of it (Pavlov and Buonsanto, 1997) to calculate an equivalent plasma drift velocity. To overcome this problem, we use the approach of Eqs.…”

“…During quiet conditions the modeled hmF2 are very close to hmF2 IRI . If we have the observed peak height altitude, hmF2 exp , of the F2-layer in the northern or southern hemispheres then the algorithm developed by Richards (1991) with our modi®cation (Pavlov and Buonsanto, 1997) is used to calculate d for this hemisphere…”

Subauroral red arcs as a conjugate phenomenon: comparison of OV1-10 satellite data with numerical calculations

“…(A13 , A14) given by Pavlov (1994). The large uncertainities in the calculated h lead to large errors in the modeled electron densities and peak height altitude, hmF2, of the F2-layer (Richards, 1991;Pavlov, 1994). This problem was largely overcome when Richards (1991) developed a technique for deriving equivalent neutral winds from the observed hmF2.…”

“…The large uncertainities in the calculated h lead to large errors in the modeled electron densities and peak height altitude, hmF2, of the F2-layer (Richards, 1991;Pavlov, 1994). This problem was largely overcome when Richards (1991) developed a technique for deriving equivalent neutral winds from the observed hmF2. Ideally, the observed hmF2 should be available for several hours before the time of the comparison, but very often only a limited set of hmF2 measurements is available or we have not got the observed hmF2 and thus cannot use the method developed by Richards (1991) or our modi®cation of this method (Pavlov and Buonsanto, 1997) to calculate an equivalent plasma drift velocity.…”

“…This problem was largely overcome when Richards (1991) developed a technique for deriving equivalent neutral winds from the observed hmF2. Ideally, the observed hmF2 should be available for several hours before the time of the comparison, but very often only a limited set of hmF2 measurements is available or we have not got the observed hmF2 and thus cannot use the method developed by Richards (1991) or our modi®cation of this method (Pavlov and Buonsanto, 1997) to calculate an equivalent plasma drift velocity. To overcome this problem, we can try to use hmF2 IRI given by the IRI-90 model (Bilitza, 1990) to calculate an equivalent plasma drift velocity, IRI , for some hypothetical undisturbed conditions with the same solar and time conditions as during the studied conditions:…”

“…In this study we employ model A and compare results with those from models B and C to evaluate the e ects of the uncertainties in these rate coe cients on calculated integral airglow intensities at 630 nm in the SAR-arc regions. We have no information on hmF2 and thus can use neither the method developed by Richards (1991) nor our modi®-cation of it (Pavlov and Buonsanto, 1997) to calculate an equivalent plasma drift velocity. To overcome this problem, we use the approach of Eqs.…”

“…During quiet conditions the modeled hmF2 are very close to hmF2 IRI . If we have the observed peak height altitude, hmF2 exp , of the F2-layer in the northern or southern hemispheres then the algorithm developed by Richards (1991) with our modi®cation (Pavlov and Buonsanto, 1997) is used to calculate d for this hemisphere…”

Subauroral red arcs as a conjugate phenomenon: comparison of OV1-10 satellite data with numerical calculations

How does solar eclipse influence the complex behavior of midlatitude ionosphere? Two case studies

An update to the Horizontal Wind Model (HWM): The quiet time thermosphere