Response of OH airglow temperatures to neutral air dynamics at 78°N, 16°E during the anomalous 2003–2004 winter

Dyrland, M. E.; Mulligan, F. J.; Hall, Chris M.; Sigernes, F.; Tsutsumi, Masaki; Deehr, C. S.

doi:10.1029/2009jd012726

Cited by 16 publications

(15 citation statements)

References 62 publications

(75 reference statements)

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“…This is consistent with previous observations using ground-based spectrometers or interferometers (e.g. Innis et al, 2001;Oberheide et al, 2006;French and Mulligan, 2010;Dyrland et al, 2010). However, it must be pointed out that the NOTCam measurements cover a very short time span and may be affected by gravity-wave perturbations of the climatological temperature gradient of the atmosphere represented by NRLMSISE.…”

Section: Temperature Gradientsupporting

confidence: 80%

Optimizing hydroxyl airglow retrievals from long-slit astronomical spectroscopic observations

et al. 2017

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Abstract. Astronomical spectroscopic observations from ground-based telescopes contain background emission lines from the terrestrial atmosphere's airglow. In the near infrared, this background is composed mainly of emission from Meinel bands of hydroxyl (OH), which is produced in highly excited vibrational states by reduction of ozone near 90 km. This emission contains a wealth of information on the chemical and dynamical state of the Earth's atmosphere. However, observation strategies and data reduction processes are usually optimized to minimize the influence of these features on the astronomical spectrum. Here we discuss a measurement technique to optimize the extraction of the OH airglow signal itself from routine J-, H-, and K-band long-slit astronomical spectroscopic observations. As an example, we use data recorded from a point-source observation by the Nordic Optical Telescope's intermediate-resolution spectrograph, which has a spatial resolution of approximately 100 m at the airglow layer. Emission spectra from the OH vibrational manifold from v = 9 down to v = 3, with signal-to-noise ratios up to 280, have been extracted from 10.8 s integrations. Rotational temperatures representative of the background atmospheric temperature near 90 km, the mesosphere and lower thermosphere region, can be fitted to the OH rotational lines with an accuracy of around 0.7 K. Using this measurement and analysis technique, we derive a rotational temperature distribution with v that agrees with atmospheric model conditions and the preponderance of previous work. We discuss the derived rotational temperatures from the different vibrational bands and highlight the potential for both the archived and future observations, which are at unprecedented spatial and temporal resolutions, to contribute toward the resolution of long-standing problems in atmospheric physics.

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Section: Temperature Gradientsupporting

confidence: 80%

Optimizing hydroxyl airglow retrievals from long-slit astronomical spectroscopic observations

et al. 2017

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“…The low altitudes were attributed to downwelling due to the strengthening of the polar vortex after an SSW in January–February 2004 [ Dyrland et al ., ]. A temperature increase of the order of 15 K was attributed to the lowering of the layer, so the altitude is definitely a key factor in determining the OH* temperature [ Dyrland et al ., ]. Similarly, low OH* peak altitudes were observed after the SSW in 2006 [ Winick et al ., 2009].…”

Section: Resultsmentioning

confidence: 99%

Long‐term trends and the effect of solar cycle variations on mesospheric winter temperatures over Longyearbyen, Svalbard (78°N)

2014

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This paper gives an update on the long-term trend in hydroxyl (OH*) airglow winter temperatures measured by a 1 m Ebert-Fastie spectrometer in Longyearbyen, Svalbard (78°N, 16°E), from 1983 to 2013. The temperatures are derived through synthetic fits of measured airglow spectra of the OH*(6-2) vibrational state. The data set is corrected for seasonal variations by subtracting the mean climatology. Also, solar cycle dependence is investigated. A solar response coefficient of 3.6 K ± 4.0 K/100 solar flux units (SFU) is calculated from F10.7 cm solar radio flux data. After subtraction of the climatology and solar response, the remaining long-term trend is a near-zero trend, À0.2 K ± 0.5 K/decade. Trend analysis of monthly temperatures indicates positive trends for November, January, and February and a negative trend for December, but the uncertainties are high.

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“…If simultaneous observations of the vertical volume emission rate profile of the OH band analyzed are not available, the interpretation of the temperature retrievals may be difficult. An extreme example is the dramatic decrease of the OH emission layer altitude down to about 78 km observed in early 2004 at high northern latitudes, leading to an apparent temperature increase of about 15 K (Dyrland et al, 2010). Long-term, solar cycle and seasonal variations in OH emission altitude can also lead to apparent variations in ground-based OH temperature measurements, and may interfere with the determination of the actual long-term, solar cycle and seasonal variations of upper mesospheric temperatures.…”

Section: Introductionmentioning

confidence: 99%

On the dependence of the OH<sup>*</sup> Meinel emission altitude on vibrational level: SCIAMACHY observations and model simulations

et al. 2012

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Abstract. Measurements of the OH Meinel emissions in the terrestrial nightglow are one of the standard ground-based techniques to retrieve upper mesospheric temperatures. It is often assumed that the emission peak altitudes are not strongly dependent on the vibrational level, although this assumption is not based on convincing experimental evidence. In this study we use Envisat/SCIAMACHY (Scanning Imaging Absorption spectroMeter for Atmospheric CHartographY) observations in the near-IR spectral range to retrieve vertical volume emission rate profiles of the OH(3-1), OH(6-2) and OH(8-3) Meinel bands in order to investigate whether systematic differences in emission peak altitudes can be observed between the different OH Meinel bands. The results indicate that the emission peak altitudes are different for the different vibrational levels, with bands originating from higher vibrational levels having higher emission peak altitudes. It is shown that this finding is consistent with the majority of the previously published results. The SCIAMACHY observations yield differences in emission peak altitudes of up to about 4 km between the OH(3-1) and the OH(8-3) band.The observations are complemented by model simulations of the fractional population of the different vibrational levels and of the vibrational level dependence of the emission peak altitude. The model simulations reproduce the observed vibrational level dependence of the emission peak altitude well -both qualitatively and quantitatively -if quenching by atomic oxygen as well as multi-quantum collisional relaxation by O 2 is considered. If a linear relationship between emission peak altitude and vibrational level is assumed, then a peak altitude difference of roughly 0.5 km per vibrational level is inferred from both the SCIAMACHY observations and the model simulations.

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Response of OH airglow temperatures to neutral air dynamics at 78°N, 16°E during the anomalous 2003–2004 winter

Cited by 16 publications

References 62 publications

Optimizing hydroxyl airglow retrievals from long-slit astronomical spectroscopic observations

Optimizing hydroxyl airglow retrievals from long-slit astronomical spectroscopic observations

Long‐term trends and the effect of solar cycle variations on mesospheric winter temperatures over Longyearbyen, Svalbard (78°N)

On the dependence of the OH<sup>*</sup> Meinel emission altitude on vibrational level: SCIAMACHY observations and model simulations

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Response of OH airglow temperatures to neutral air dynamics at 78°N, 16°E during the anomalous 2003–2004 winter

Cited by 16 publications

References 62 publications

Optimizing hydroxyl airglow retrievals from long-slit astronomical spectroscopic observations

Optimizing hydroxyl airglow retrievals from long-slit astronomical spectroscopic observations

Long‐term trends and the effect of solar cycle variations on mesospheric winter temperatures over Longyearbyen, Svalbard (78°N)

On the dependence of the OH&lt;sup&gt;*&lt;/sup&gt; Meinel emission altitude on vibrational level: SCIAMACHY observations and model simulations

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On the dependence of the OH<sup>*</sup> Meinel emission altitude on vibrational level: SCIAMACHY observations and model simulations