C. K. Mutiso scite author profile

We have examined Michelson Interferometer OH airglow temperature data to investigate solar cycle and long‐term variations of mesospheric temperatures at South Pole Station (SPS), Antarctica (90°S). The data set used here is continuous (24 hours a day) and taken during 1994–2004 austral winters. We have used a Multiple Linear Regression (MLR) technique to elucidate solar cycle and the trend term in the MI temperature time series data. The 11‐year time series of OH rotational temperature shows a strong correlation with F10.7 radio flux (R = 0.60). The amplitude of solar cycle response seen in the mesopause temperature records at South Pole is about 0.04 ± 0.01 K/sfu (Solar Flux Units), however, the trend term is statistically insignificant and is about 0.1 ± 0.2 K/year. Superposed epoch studies have been carried out in order to determine climatological variations in OH temperatures above South Pole derived from 11 years of austral winter observations. The mean amplitude of this variation is about 12.6 K and its maximum occurs near 30 May which is in agreement with the Fabry‐Perot Spectrometer (FPS) observations of OH temperatures at SPS (Hernandez, 2003). However, whereas Hernandez (2003) reported 35 K cooling in 2002, MI OH temperatures at SPS do not show any significant deviation from previous years.

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First estimates of volume distribution of HF-pump enhanced emissions at 6300 and 5577 Å: a comparison between observations and theory

Gustavsson

Kosch

Wong³

et al. 2008

Ann. Geophys.

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Abstract. We present bi-static observations of radio-wave induced optical emissions at 6300 and 5577 Å from a night-time radio-induced optical emission ionospheric pumping experiment at the HIPAS (Fairbanks) facility in Alaska. The optical observations were made at HIPAS and from HAARP located 285 km south-east. From these observations the altitude distribution of the emissions is estimated with tomography-like methods. These estimates are compared with theoretical models. Other diagnostics used to support the theoretical calculations include the new Poker Flat AMISR UHF radar near HIPAS. We find that the altitude distribution of the emissions agree with electron transport modeling with a source of accelerated electrons located 20 km below the upper-hybrid altitude.

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Previously unreported optical emissions generated during ionospheric heating

Mutiso¹,

Hughes²,

Sivjee³

et al. 2008

Geophysical Research Letters

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Several radio‐induced optical emissions were generated during an ionospheric heating experiment performed at the High Power Auroral Stimulation (HIPAS) facility near Two Rivers, Alaska. The O+ 732–733 nm and O(3Do) 799.0 nm emissions, previously unreported from ionospheric heating experiments, were detected, in addition to the already documented O(3P) 844.6 nm and O(5P) 777.4 nm emissions. Maximum emission intensity was observed in the magnetic zenith, when the heater was transmitting continuous wave O‐mode, at a frequency of 2.85 MHz. A modified Czerny‐Turner grating spectrometer was used to acquire high resolution optical spectra of the induced emissions, which were synchronized to the heater duty cycle. Candidate mechanisms for the production of the radio‐induced emissions, which occurred before the “double resonance” condition, are presented.

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First incoherent scatter radar observations of ionospheric heating on the second electron gyro-harmonic

Kosch

Gustavsson

Heinselman

et al. 2009

Journal of Atmospheric and Solar-Terrestrial Physics

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a b s t r a c tWe report first results from a unique experiment performed at the HIPAS ionospheric modification facility in conjunction with the Poker Flat incoherent scatter radar in Alaska. High-power radio waves at 2.85 MHz, which corresponds to the second electron gyro-harmonic at $ 245 km altitude, were transmitted into the nighttime ionosphere. Clear evidence of F-region ionospheric electron temperature enhancements were found, for the first time at this pump frequency, maximizing when the pump frequency is close to the second gyro-harmonic and double resonance. This is consistent with previous pump-enhanced artificial optical observations. We estimate the plasma heating efficiency to be approximately double that for higher pump frequencies.

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Thermospheric neutral temperatures derived from charge-exchange produced N<sub>2</sub><sup>+</sup> Meinel (1,0) rotational distributions

et al. 2013

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Abstract. Thermalized rotational distributions of neutral and ionized N2 and O2 have long been used to determine neutral temperatures (Tn) during auroral conditions. In both bright E-region (≲150 km) auroras, and in higher-altitude auroras, spectral distributions of molecular emissions employed to determine Tn in the E-region cannot likewise be used to obtain Tn in the F-region. Nevertheless, charge-exchange reactions between high-altitude (≳130 km) species provide an exception to this situation. In particular, the charge-exchange reaction O+(2D) + N2(X) → N+2(A2Πu, ν' = 1 + O(3P) yields thermalized N2+ Meinel (1,0) emissions, which, albeit weak, can be used to derive neutral temperatures at altitudes of ~130 km and higher. In this work, we present N2+ Meinel (1,0) rotational temperatures and brightnesses obtained at Svalbard, Norway, during various auroral conditions. We calculate Tn at thermospheric altitudes of 130–180 km from thermalized rotational populations of N2+ Meinel (1,0); these emissions are excited by soft electron (≲1 keV) impact and charge-exchange reactions. We model the contributions of the respective excitation mechanisms, and compare derived brightnesses to observations. The agreement between the two is good. Emission heights obtained from optical data, modeling, and ISR data are consistent. Obtaining thermospheric Tn from charge-exchange excited N2+ Meinel (1,0) emissions provides an additional means of remotely sensing the neutral atmosphere, although certain limiting conditions are necessary. These include precipitation of low-energy electrons, and a non-sunlit emitting layer.

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C. K. Mutiso

Solar cycle signature and secular long‐term trend in OH airglow temperature observations at South Pole, Antarctica

First estimates of volume distribution of HF-pump enhanced emissions at 6300 and 5577 Å: a comparison between observations and theory

Previously unreported optical emissions generated during ionospheric heating

First incoherent scatter radar observations of ionospheric heating on the second electron gyro-harmonic

Thermospheric neutral temperatures derived from charge-exchange produced N<sub>2</sub><sup>+</sup> Meinel (1,0) rotational distributions

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C. K. Mutiso

Solar cycle signature and secular long‐term trend in OH airglow temperature observations at South Pole, Antarctica

First estimates of volume distribution of HF-pump enhanced emissions at 6300 and 5577 Å: a comparison between observations and theory

Previously unreported optical emissions generated during ionospheric heating

First incoherent scatter radar observations of ionospheric heating on the second electron gyro-harmonic

Thermospheric neutral temperatures derived from charge-exchange produced N&lt;sub&gt;2&lt;/sub&gt;&lt;sup&gt;+&lt;/sup&gt; Meinel (1,0) rotational distributions

Contact Info

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Resources

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Thermospheric neutral temperatures derived from charge-exchange produced N<sub>2</sub><sup>+</sup> Meinel (1,0) rotational distributions