O. Jokiaho scite author profile

Abstract. Measurements of N21P auroral emissions from the (4,1) and (5,2) bands have been made at high temporal and spatial resolution in the region of the magnetic zenith. The instrument used was the auroral imager ASK, situated at Ramfjordmoen, Norway (69.6 N, 19.2 E) on 22 October 2006. Measurements from the European Incoherent Scatter Radar (EISCAT) have been combined with the optical measurements, and incorporated into an ionospheric model to obtain height profiles of electron density and emission rates of the N21P bands. The radar data provide essential verification that the energy flux used in the model is correct. One of the most important inputs to the model is the cross section for excitation to the B3Πg electronic state, as well as the cross sections to higher states from which cascading into the B state occurs. The balance equations for production and loss of the populations of all levels in each state are solved in order to find the cascade contributions. Several sets of cross sections have been considered, and selected cross sections have been used to construct "emission" cross sections for the observed bands. The resulting brightnesses are compared with those measured by ASK. The importance of specific contributions from cascading is found, with more than 50% of the total brightness resulting from cascading. The cross sections used are found to produce a range of brightnesses well within the uncertainty of both the modelled and measured values.

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Rotational temperature of N2+ (0,2) ions from spectrographic measurements used to infer the energy of precipitation in different auroral forms and compared with radar measurements

Jokiaho

Lanchester

Ivchenko³

et al. 2008

Ann. Geophys.

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Abstract. High resolution spectral data are used to estimate neutral temperatures at auroral heights. The data are from the High Throughput Imaging Echelle Spectrograph (HiTIES) which forms part of the Spectrographic Imaging Facility (SIF), located at Longyearbyen, Svalbard in Norway. The platform also contains photometers and a narrow angle auroral imager. Quantum molecular spectroscopy is used for modelling N + 2 1NG (0,2), which serves as a diagnostic tool for neutral temperature and emission height variations. The theoretical spectra are convolved with the instrument function and fitted to measured rotational transition lines as a function of temperature. Measurements were made in the magnetic zenith, and along a meridian slit centred on the magnetic zenith. In the results described, the high spectral resolution of the data (0.08 nm) allows an error analysis to be performed more thoroughly than previous findings, with particular attention paid to the correct subtraction of background, and to precise wavelength calibration. Supporting measurements were made with the Svalbard Eiscat Radar (ESR). Estimates were made from both optical and radar observations of the average energy of precipitating electrons in different types of aurora. These provide confirmation that the spectral results are in agreement with the variations observed in radar profiles. In rayed aurora the neutral temperature was highest (800 K) and the energy lowest (1 keV). In a bright curling arc, the temperature at the lower border was about 550 K, corresponding to energies of 2 keV. The radar and modelling results confirm that these average values are a lower limit for an estimation of the characteristic energy. In each event the energy distribution is clearly made up of more than one spectral shape. This work emphasises the need for high time resolution as well as high spectral resolution. The present work is the first to provide rotational temperatures Correspondence to: O. Jokiaho (opj100@phys.soton.ac.uk) using a method which pays particular attention to errors in measurement and fitting, and background subtraction.

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RELATIVE BRIGHTNESS OF THE O⁺(²D-²P) DOUBLETS IN LOW-ENERGY AURORAE

Whiter

Lanchester

Gustavsson

et al. 2014

ApJ

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The ratio of the emission line doublets from O + at 732.0 nm (I 732) and 733.0 nm (I 733) has been measured in auroral conditions of low-energy electron precipitation from Svalbard (78. • 20 north, 15. • 83 east). Accurate determination of R = I 732 /I 733 provides a powerful method for separating the density of the O + 2 P o 1/2,3/2 levels in modeling of the emissions from the doublets. A total of 383 spectra were included from the winter of 2003-2004. The value obtained is R = I 732 /I 733 = 1.38 ± 0.02, which is higher than theoretical values for thermal equilibrium in fully ionized plasma, but is lower than reported measurements by other authors in similar auroral conditions. The continuity equations for the densities of the two levels are solved for different conditions, in order to estimate the possible variations of R. The results suggest that the production of ions in the two levels from O (3 P 1) and O (3 P 2) does not follow the statistical weights, unlike astrophysical calculations for plasmas in nebulae. The physics of auroral impact ionization may account for this difference, and therefore for the raised value of R. In addition, the auroral solution of the densities of the ions, and thus of the value of R, is sensitive to the temperature of the neutral atmosphere. Although the present work is a statistical study, it shows that it is necessary to determine whether there are significant variations in the ratio resulting from non-equilibrium conditions, from auroral energy deposition, large electric fields, and changes in temperature and composition.

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Resonance scattering by auroral N2+: steady state theory and observations from Svalbard

Jokiaho

Lanchester

Ivchenko³

2009

Ann. Geophys.

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Abstract. Studies of auroral energy input at high latitudes often depend on observations of emissions from the first negative band of ionised nitrogen. However, these emissions are affected by solar resonance scattering, which makes photometric and spectrographic measurements difficult to interpret. This work is a statistical study from Longyearbyen, Svalbard, Norway, during the solar minimum between January and March 2007, providing a good coverage in shadow height position and precipitation conditions. The High Throughput Imaging Echelle Spectrograph (HiTIES) measured three bands of N It is shown that in sunlit aurora, the brightness of the (0,1) band is enhanced, with the scattered contribution increasing with decreasing energy of precipitation (10-fold enhancements for energies of 100 eV). The higher vibrational bands are enhanced even more significantly. In sunlit aurora the observed 1N (1,2)/(0,1) and (2,3)/(0,1) ratios increase as a function of decreasing precipitation energy, as predicted by theory. In non-sunlit aurora the N

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Modelling N21P contamination in auroral O+ emissions

Spry

Jokiaho

Lanchester

et al. 2014

Journal of Atmospheric and Solar-Terrestrial Physics

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O. Jokiaho

Modelling of N<sub>2</sub>1P emission rates in aurora using various cross sections for excitation

Rotational temperature of N<sub>2</sub><sup>+</sup> (0,2) ions from spectrographic measurements used to infer the energy of precipitation in different auroral forms and compared with radar measurements

RELATIVE BRIGHTNESS OF THE O⁺(²D-²P) DOUBLETS IN LOW-ENERGY AURORAE

Resonance scattering by auroral N<sub>2</sub><sup>+</sup>: steady state theory and observations from Svalbard

Modelling N21P contamination in auroral O+ emissions

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O. Jokiaho

Modelling of N&lt;sub&gt;2&lt;/sub&gt;1P emission rates in aurora using various cross sections for excitation

Rotational temperature of N&lt;sub&gt;2&lt;/sub&gt;&lt;sup&gt;+&lt;/sup&gt; (0,2) ions from spectrographic measurements used to infer the energy of precipitation in different auroral forms and compared with radar measurements

RELATIVE BRIGHTNESS OF THE O+(2D-2P) DOUBLETS IN LOW-ENERGY AURORAE

Resonance scattering by auroral N&lt;sub&gt;2&lt;/sub&gt;&lt;sup&gt;+&lt;/sup&gt;: steady state theory and observations from Svalbard

Modelling N21P contamination in auroral O+ emissions

Contact Info

Product

Resources

About

Modelling of N<sub>2</sub>1P emission rates in aurora using various cross sections for excitation

Rotational temperature of N<sub>2</sub><sup>+</sup> (0,2) ions from spectrographic measurements used to infer the energy of precipitation in different auroral forms and compared with radar measurements

RELATIVE BRIGHTNESS OF THE O⁺(²D-²P) DOUBLETS IN LOW-ENERGY AURORAE

Resonance scattering by auroral N<sub>2</sub><sup>+</sup>: steady state theory and observations from Svalbard