Diurnal variation in middle atmospheric ozone by ground based microwave radiometry at Ny-Ålesund over 1 year

Schranz, Franziska; Vidal, Susana Fernandez; Kämpfer, Niklaus; Palm, Mathias

doi:10.5194/acp-2017-1080

Cited by 2 publications

(3 citation statements)

References 20 publications

(28 reference statements)

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“…8). In the mesosphere a diurnal cycle was detected in spring and autumn whereas in the stratosphere at 10 hPa the diurnal variation is seen in mid summer during the period of polar day (Schranz et al, 2018).…”

Section: H 2 O Time Series Of Miawara-cmentioning

confidence: 93%

“…Therefore GROMOS-C observes subsequently in the four cardinal directions (N-E-S-W) at 22 • elevation with a sampling time of 4 seconds. At the Arctic location of Ny-Ålesund this allows observations in and outside of the polar vortex if the vortex edge is close to Ny-Ålesund (Schranz et al, 2018). The retrieval of ozone and wind is performed with Qpack (Eriksson et al, 2005) and ARTS2 (Eriksson et al, 2011), using an optimal estimation method (Rodgers, 1976).…”

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confidence: 99%

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Investigation of Arctic middle-atmospheric dynamics using 3 years of H2O and O3 measurements from microwave radiometers at Ny-Ålesund

Schranz¹,

Tschanz²,

Rüfenacht³

et al. 2019

Preprint

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Abstract. We use 3 years of water vapour and ozone measurements to analyse dynamical events in the polar middle atmosphere such as sudden stratospheric warmings (SSW), polar vortex shifts, water vapour descent rates and periodicities. The measurements were performed with the two ground-based microwave radiometers MIAWARA-C and GROMOS-C which are co-located at the AWIPEV research base at Ny-&#197;lesund, Svalbard (79&#176;&#8201;N, 12&#176;&#8201;E) since September 2015. The almost continuous datasets of water vapour and ozone are characterised by a high time resolution in the order of hours. A thorough intercomparison of these datasets with models and measurements from satellite, ground-based and in-situ instruments was performed. In the upper stratosphere and lower mesosphere the MIAWARA-C profiles agree within 5&#8201;% with SD-WACCM simulations and ACE-FTS measurements whereas AuraMLS measurements show an average offset of 10&#8211;15&#8201;% depending on altitude but constant in time. Stratospheric GROMOS-C profiles are within 5&#8201;% of the satellite instruments AuraMLS and ACE-FTS and the ground-based microwave radiometer OZORAM which is also located at Ny-&#197;lesund. During these first three years of the measurement campaign typical phenomena of the Arctic middle atmosphere took place and we analysed their signatures in the water vapour and ozone datasets. Inside of the polar vortex in autumn we found the descent rate of mesospheric water vapour to be 435&#8201;m/day on average. In early 2017 distinct increases in mesospheric water vapour of about 2&#8201;ppm were observed when the polar vortex was displaced and midlatitude air was brought to Ny-&#197;lesund. Two major sudden stratospheric warmings took place in March 2016 and February 2018 where ozone enhancements of up to 4&#8201;ppm were observed. The zonal wind reversals accompanying a major SSW were captured in the GROMOS-C wind profiles which are retrieved from the ozone spectra. After the SSW in February 2018 the polar vortex re-established and the water vapour descent rate in the mesosphere was 355&#8201;m/day. In the water vapour and ozone time series signatures of atmospheric waves with periods close to 2, 5, 10 and 16 days were found.

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Section: H 2 O Time Series Of Miawara-cmentioning

confidence: 93%

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confidence: 99%

Investigation of Arctic middle-atmospheric dynamics using 3 years of H2O and O3 measurements from microwave radiometers at Ny-Ålesund

Schranz¹,

Tschanz²,

Rüfenacht³

et al. 2019

Preprint

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“…In contrast to many other observation methods, observations by millimeter-wave radiometer (MWR) make it possible to obtain ozone mixing ratios with high temporal resolution (~1 hr) over a wide altitude range from the stratosphere to the lower mesosphere (e.g., Moreira et al, 2016;Parrish et al, 2014;Schranz et al, 2018;Solomonov et al, 2012). The largest positive ozone trend after 2000 was observed around 1 hPa in the Northern midlatitude, owing mainly to a decline in the atmospheric abundance of chlorine (WMO, 2018); however, factors that cause interannual ozone variations at that pressure level have been examined to a lesser degree.…”

Section: Introductionmentioning

confidence: 99%

Interannual Variation of Upper Stratospheric Ozone in the Northern Midlatitudes in Early Winter Caused by Planetary Waves

et al. 2019

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Ozone mixing ratios in the upper stratosphere, observed with a millimeter‐wave radiometer at Rikubetsu (43.46°N, 143.77°E), Japan, from November 1999 to February 2017 showed both interannual and seasonal variation, which was characterized by a winter maximum and a summer minimum. During the study period, the summer minima were nearly constant whereas the winter maxima varied interannually and also displayed short‐term variability. The observed ozone mixing ratios at 1 hPa were anticorrelated with temperature at 1 hPa from MERRA‐2 data. The slope of the relationship between the logarithm of ozone concentration and the reciprocal of temperature differed between winter data and both summer and annual data. Therefore, we inferred that both chemistry and dynamics affect short‐term variation of ozone mixing ratios in winter. We then examined the contribution of the polar vortex to interannual variations in ozone and temperature at 1 hPa. When the polar vortex was strong, wave number‐1 planetary waves at high latitude propagated toward the midlatitudes instead of vertically. The vertical component of the wave number‐1 Eliassen‐Palm flux along 43°N at 1 hPa was strongly correlated with zonal mean zonal wind along 60°N at 50 hPa. When the zonal mean westerly wind was strong in December, upper stratospheric (~1 hPa) temperatures over Rikubetsu and over a point on the opposite side of the globe (by longitude) were significantly lower and higher, respectively, than the climatological temperature. Thus, planetary wave propagation related to zonal mean westerly wind strength induced early winter interannual variation in upper stratospheric ozone in the midlatitudes.

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Diurnal variation in middle atmospheric ozone by ground based microwave radiometry at Ny-Ålesund over 1 year

Cited by 2 publications

References 20 publications

Investigation of Arctic middle-atmospheric dynamics using 3 years of H<sub>2</sub>O and O<sub>3</sub> measurements from microwave radiometers at Ny-Ålesund

Investigation of Arctic middle-atmospheric dynamics using 3 years of H<sub>2</sub>O and O<sub>3</sub> measurements from microwave radiometers at Ny-Ålesund

Interannual Variation of Upper Stratospheric Ozone in the Northern Midlatitudes in Early Winter Caused by Planetary Waves

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Diurnal variation in middle atmospheric ozone by ground based microwave radiometry at Ny-Ålesund over 1 year

Cited by 2 publications

References 20 publications

Investigation of Arctic middle-atmospheric dynamics using 3 years of H&lt;sub&gt;2&lt;/sub&gt;O and O&lt;sub&gt;3&lt;/sub&gt; measurements from microwave radiometers at Ny-Ålesund

Investigation of Arctic middle-atmospheric dynamics using 3 years of H&lt;sub&gt;2&lt;/sub&gt;O and O&lt;sub&gt;3&lt;/sub&gt; measurements from microwave radiometers at Ny-Ålesund

Interannual Variation of Upper Stratospheric Ozone in the Northern Midlatitudes in Early Winter Caused by Planetary Waves

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Investigation of Arctic middle-atmospheric dynamics using 3 years of H<sub>2</sub>O and O<sub>3</sub> measurements from microwave radiometers at Ny-Ålesund

Investigation of Arctic middle-atmospheric dynamics using 3 years of H<sub>2</sub>O and O<sub>3</sub> measurements from microwave radiometers at Ny-Ålesund