Middle atmospheric O3, CO, N2O, HNO3, and temperature profiles during the warm Arctic winter 2001–2002

Muscari, Giovanni; Sarra, Alcide di; Zafra, R. L. de; Lucci, Francesco; Baordo, F.; Angelini, F.; Fiocco, G.

doi:10.1029/2006jd007849

Cited by 25 publications

(73 citation statements)

References 33 publications

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“…Therefore, by means of the observed line shape together with pressure and temperature vertical profiles, a mathematical deconvolution process allows finding the emitting molecule's concentration as a function of altitude. The overall spectral band pass and resolution of the GBMS are key elements to determine the 17–75 km altitude range where trace gases concentration can be measured [e.g., see Muscari et al , 2007, and references therein]. For water vapor, we do not observe an H 2 O emission line (e.g., at 183 or 325 GHz) but rather the emission from the H 2 O continuum existing between emission lines.…”

Section: Gbms Observing Techniquementioning

confidence: 99%

Measurements of low amounts of precipitable water vapor by millimeter wave spectroscopy: An intercomparison with radiosonde, Raman lidar, and Fourier transform infrared data

Fiorucci¹,

Muscari²,

Bianchi³

et al. 2008

J. Geophys. Res.

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[1] Observations of very low amounts of precipitable water vapor (PWV) by means of the Ground-Based Millimeter wave Spectrometer (GBMS) are discussed. Low amounts of column water vapor (between 0.5 and 4 mm) are typical of high mountain sites and polar regions, especially during winter, and are difficult to measure accurately because of the lack of sensitivity of conventional instruments to such low PWV contents. The technique used involves the measurement of atmospheric opacity in the range between 230 and 280 GHz with a spectral resolution of 4 GHz, followed by the conversion to precipitable water vapor using a linear relationship. We present the intercomparison of this data set with simultaneous PWV observations obtained with Vaisala RS92k radiosondes, a Raman lidar, and an IR Fourier transform spectrometer. These sets of measurements were carried out during the primary field campaign of the Earth Cooling by Water vapor Radiation (ECOWAR) project which took place at Breuil-Cervinia (45.9°N, 7.6°E, elevation 1990 m) and Plateau Rosa (45.9°N, 7.7°E, elevation 3490 m), Italy, from 3 to 16 March 2007. GBMS PWV measurements show a good agreement with the other three data sets exhibiting a mean difference between observations of '9%. The considerable number of data points available for the GBMS versus lidar PWV correlation allows an additional analysis which indicates negligible systematic differences between the two data sets.

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Section: Gbms Observing Techniquementioning

confidence: 99%

Measurements of low amounts of precipitable water vapor by millimeter wave spectroscopy: An intercomparison with radiosonde, Raman lidar, and Fourier transform infrared data

Fiorucci¹,

Muscari²,

Bianchi³

et al. 2008

J. Geophys. Res.

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“…Whereas seasonal ozone depletion is regularly observed in the Antarctic since more than 30 years, significant depletion of the Arctic ozone layer sporadically occurred in some years (e.g. 1999-2000, 2001-2002, and 2004-2005) during late winter/spring period (January-April) (Dahlback, 2002;Hessen, 2002;Fahey, 2003;Jin et al, 2006;Muscari et al, 2007). Even under non-depleted ozone conditions, UV-B still presents potential negative impacts to photosynthetic organisms.…”

Section: Introductionmentioning

confidence: 99%

The vegetative arctic freshwater green alga Zygnema is insensitive to experimental UV exposure

Holzinger

Roleda

Lütz

2009

Micron

121

139

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“…Starting in 1993, observations of stratospheric O 3 and HNO 3 have been carried out by means of a Ground-Based Millimeter-wave Spectrometer (GBMS) at different sites in both hemispheres, at polar and mid-latitudes (e.g., de Zafra et al, 1997;Muscari et al, 2007;Santee et al, 2007). GBMS data have contributed to shed light on processes related to the global ozone decline and to the dramatic ozone loss occurring over the Antarctic continent every spring.…”

Section: Introductionmentioning

confidence: 99%

Ground-based stratospheric O3 and HNO3 measurements at Thule, Greenland: an intercomparison with Aura MLS observations

et al. 2013

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Abstract. In response to the need for improving our understanding of the evolution and the interannual variability of the winter Arctic stratosphere, in January 2009 a GroundBased Millimeter-wave Spectrometer (GBMS) was installed at the Network for the Detection of Atmospheric Composition Change (NDACC) site in Thule (76.5 • N, 68.8 • W), Greenland. In this work, stratospheric GBMS O 3 and HNO 3 vertical profiles obtained from Thule during the winters 2010 (HNO 3 only), 2011 and 2012 are characterized and intercompared with co-located measurements of the Aura Microwave Limb Sounder (MLS) experiment. Using a recently developed algorithm based on Optimal Estimation, we find that the GBMS O 3 retrievals show good sensitivity (> 80 %) to atmospheric variations between ∼ 17 and ∼ 50 km, where their 1σ uncertainty is estimated to be the larger of ∼ 11 % or 0.2 ppmv. Similarly, HNO 3 profiles can be considered for scientific use between ∼ 17 and ∼ 45 km altitude, with a 1σ uncertainty that amounts to the larger of 15 % or 0.2 ppbv. Comparisons with Aura MLS version 3.3 observations show that, on average, GBMS O 3 mixing ratios are biased negatively with respect to MLS throughout the stratosphere, with differences ranging between ∼ 0.3 ppmv (8 %) and 0.9 ppmv (18 %) in the 17-50 km vertical range. GBMS HNO 3 values display instead a positive bias with respect to MLS up to 26 km, reaching a maximum of ∼ 1 ppbv (10 %) near the mixing ratio profile peak. O 3 and HNO 3 values from the two datasets prove to be well correlated at all altitudes, although their correlations worsen at the lower end of the altitude ranges considered. Column contents of GBMS and MLS O 3 (from 20 km upwards) and HNO 3 (from 17 km upwards) correlate very well and indicate that GBMS measurements can provide valuable estimates of column interannual and seasonal variations for these compounds.

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Middle atmospheric O₃, CO, N₂O, HNO₃, and temperature profiles during the warm Arctic winter 2001–2002

Cited by 25 publications

References 33 publications

Measurements of low amounts of precipitable water vapor by millimeter wave spectroscopy: An intercomparison with radiosonde, Raman lidar, and Fourier transform infrared data

Measurements of low amounts of precipitable water vapor by millimeter wave spectroscopy: An intercomparison with radiosonde, Raman lidar, and Fourier transform infrared data

The vegetative arctic freshwater green alga Zygnema is insensitive to experimental UV exposure

Ground-based stratospheric O<sub>3</sub> and HNO<sub>3</sub> measurements at Thule, Greenland: an intercomparison with Aura MLS observations

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Middle atmospheric O3, CO, N2O, HNO3, and temperature profiles during the warm Arctic winter 2001–2002

Cited by 25 publications

References 33 publications

Measurements of low amounts of precipitable water vapor by millimeter wave spectroscopy: An intercomparison with radiosonde, Raman lidar, and Fourier transform infrared data

Measurements of low amounts of precipitable water vapor by millimeter wave spectroscopy: An intercomparison with radiosonde, Raman lidar, and Fourier transform infrared data

The vegetative arctic freshwater green alga Zygnema is insensitive to experimental UV exposure

Ground-based stratospheric O&lt;sub&gt;3&lt;/sub&gt; and HNO&lt;sub&gt;3&lt;/sub&gt; measurements at Thule, Greenland: an intercomparison with Aura MLS observations

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Middle atmospheric O₃, CO, N₂O, HNO₃, and temperature profiles during the warm Arctic winter 2001–2002

Ground-based stratospheric O<sub>3</sub> and HNO<sub>3</sub> measurements at Thule, Greenland: an intercomparison with Aura MLS observations