A comparison of 11-year mesospheric and lower thermospheric winds determined by meteor and MF radar at 69 ° N

Wilhelm, Sven; Stober, Gunter; Chau, Jorge L.

doi:10.5194/angeo-35-893-2017

Cited by 40 publications

(50 citation statements)

References 33 publications

(53 reference statements)

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“…The specular meteor radars (SMRs) located at the sites of Andenes (69.3 • N, 16 • E) and Juliusruh (54.6 • N, 13.3 • E) have been extensively used to study neutral winds and atmospheric waves in the MLT region (e.g., Chau et al, 2015;Hoffmann et al, 2007Hoffmann et al, , 2010Conte et al, 2017Conte et al, , 2018Wilhelm et al, 2017). Combined, they provide continuous measurements for a set that is currently comprised of more than 15 years worth of data.…”

Section: Discussionmentioning

confidence: 99%

Middle‐ and High‐Latitude Mesosphere and Lower Thermosphere Mean Winds and Tides in Response to Strong Polar‐Night Jet Oscillations

2019

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The dynamical behavior of the mesosphere and lower thermosphere (MLT) region during strongly disturbed wintertime conditions commonly known as polar‐night jet oscillations (PJOs) is described in detail and compared to other wintertime conditions. For this purpose, wind measurements provided by two specular meteor radars located at Andenes (69°N, 16°E) and Juliusruh (54°N, 13°E) are used to estimate horizontal mean winds and tides as an observational basis. Winds and tidal main features are analyzed and compared for three different cases: major sudden stratospheric warming (SSW) with (a) strong PJO event, (b) non‐PJO event, and (c) no major SSWs. We show that the distinction into strong PJOs, non‐PJOs, and winters with no major SSWs is better suited to identify differences in the behavior of the mean winds and tides during the boreal winter. To assess the impact of the stratospheric disturbed conditions on the MLT region, we investigate the 30‐year nudged simulation by the Extended Canadian Middle Atmosphere Model. Analysis of geopotential height disturbances suggests that changes in the location of the polar vortex at mesospheric heights are responsible for the jets observed in the MLT mean winds during strong PJOs, which in turn influence the evolution of semidiurnal tides by increasing or decreasing their amplitudes depending on the tidal component.

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Section: Discussionmentioning

confidence: 99%

Middle‐ and High‐Latitude Mesosphere and Lower Thermosphere Mean Winds and Tides in Response to Strong Polar‐Night Jet Oscillations

2019

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“…By using the methodology of Dowdy et al () it is possible to extend this study to measurements of vertical winds in the summertime MLT. However, MFR observations can underestimate the magnitude of the wind motions, as discussed by Wilhelm et al () and Reid et al (). Wind measurements with a colocated meteor wind radar are used to calibrate the MFR observations.…”

Section: Introductionmentioning

confidence: 93%

“…Since the method for determining vertical winds requires accurate estimates of

\overset{v}{true} false(z false)

(equation ) there was a need to correct the MFR wind speeds. This was achieved by intercomparing the MFR wind components against simultaneous measurements made with a colocated 33‐MHz meteor wind radar (see Reid et al, ), so the MFR wind speeds can be corrected, as recently discussed by Wilhelm et al () and Reid et al (). A similar approach to that used by Reid et al () is adopted here to estimate the biases with height in the MFR wind components using the MWR data that are available from 2005 to 2018.…”

Section: Instrumentation and Radar Comparisonsmentioning

confidence: 99%

Trends and Variability in Vertical Winds in the Southern Hemisphere Summer Polar Mesosphere and Lower Thermosphere

et al. 2019

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Direct measurement of mean vertical velocities in the mesosphere‐lower thermosphere (60–110 km) is not possible due to their small values. Here we derive vertical velocities using the divergence of the mean meridional wind over the Antarctic summer pole using MF radar wind measurements made at Davis Station (69°S, 78°E) between 1994 and 2018. Estimates of vertical velocity are restricted to a 21‐day period centered just after solstice when the equatorward wind reaches its maximum value of about 15 m s−1 at heights near 90 km. The Medium Frequency (MF) radar winds are calibrated against colocated meteor wind radar observations. Neutral densities required for the vertical wind calculations are obtained from zonally averaged temperature measurements obtained by the MLS instrument aboard the AURA satellite. The estimated vertical velocities have peak values varying between 2 and 6 cm s−1 with significant interannual variability. While the peak values do not show significant long‐term change, there is a long‐term decrease in the mean height of maximum winds of about 0.6 km per decade that is statistically significant. The interannual variability is linked to the date of transition in the stratospheric zonal circulation from winter eastward to summer westward flow. Meridional and vertical velocities are smaller and peak at lower altitudes during early transitions (20–30 days prior to solstice) than is the case for late transitions that occur at solstice or later.

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“…These should appear as constant offsets to the measurements at a particular latitude. Especially the effect of the diurnal tide, which appears to be the strongest tidal component in the middle atmosphere, is strongly reduced by the averaging over the measurements during the satellite's overpasses in the ascending and descending orbit spaced by 12 h. A more detailed discussion on the impact of tides on MLS measurements can be found for example in Lieberman et al (2015) and Xu et al (2009). It should also be remembered that, in contrast to the mesopause region, tides are usually weak in the stratosphere and lower mesosphere (e.g.…”

Section: Geostrophic Wind From the Mls Geopotential Height Fieldmentioning

confidence: 99%

Intercomparison of middle-atmospheric wind in observations and models

et al. 2018

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Wind profile information throughout the entire upper stratosphere and lower mesosphere (USLM) is important for the understanding of atmospheric dynamics but became available only recently, thanks to developments in remote sensing techniques and modelling approaches. However, as wind measurements from these altitudes are rare, such products have generally not yet been validated with (other) observations. This paper presents the first long-term intercomparison of wind observations in the USLM by colocated microwave radiometer and lidar instruments at Andenes, Norway (69.3 • N, 16.0 • E). Good correspondence has been found at all altitudes for both horizontal wind components for nighttime as well as daylight conditions. Biases are mostly within the random errors and do not exceed 5-10 m s −1 , which is less than 10 % of the typically encountered wind speeds. Moreover, comparisons of the observations with the major reanalyses and models covering this altitude range are shown, in particular with the recently released ERA5, ECMWF's first reanalysis to cover the whole USLM region. The agreement between models and observations is very good in general, but temporally limited occurrences of pronounced discrepancies (up to 40 m s −1 ) exist. In the article's Appendix the possibility of obtaining nighttime wind information about the mesopause region by means of microwave radiometry is investigated.

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A comparison of 11-year mesospheric and lower thermospheric winds determined by meteor and MF radar at 69 ° N

Cited by 40 publications

References 33 publications

Middle‐ and High‐Latitude Mesosphere and Lower Thermosphere Mean Winds and Tides in Response to Strong Polar‐Night Jet Oscillations

Middle‐ and High‐Latitude Mesosphere and Lower Thermosphere Mean Winds and Tides in Response to Strong Polar‐Night Jet Oscillations

Trends and Variability in Vertical Winds in the Southern Hemisphere Summer Polar Mesosphere and Lower Thermosphere

Intercomparison of middle-atmospheric wind in observations and models

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A comparison of 11-year mesospheric and lower thermospheric winds determined by meteor and MF radar at 69 ° N

Cited by 40 publications

References 33 publications

Middle‐ and High‐Latitude Mesosphere and Lower Thermosphere Mean Winds and Tides in Response to Strong Polar‐Night Jet Oscillations

Middle‐ and High‐Latitude Mesosphere and Lower Thermosphere Mean Winds and Tides in Response to Strong Polar‐Night Jet Oscillations

Trends and Variability in Vertical Winds in the Southern Hemisphere Summer Polar Mesosphere and Lower Thermosphere

Intercomparison of middle-atmospheric wind in observations and models

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A comparison of 11-year mesospheric and lower thermospheric winds determined by meteor and MF radar at 69 ° N