Condensation Nuclei Measurements in the Midlatitude (1982-2012) and Antarctic (1986-2010) Stratosphere between 20 and 35 km

©2013. The Authors. Balloon-borne stratospheric condensation nuclei (CN) measurements have been made from McMurdo Station, Antarctica (78°S), 1986-2010, and from Laramie, Wyoming (41°N), 1982 to the present. In the Antarctic region, the measurements show the formation of a layer of enhanced concentr...

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Bibliographic Details
Published in:Journal of Geophysical Research: Atmospheres
Main Authors: Campbell, P., Deshler, Terry
Format: Other Non-Article Part of Journal/Newspaper
Language:English
Published: University of Wyoming. Libraries 2014
Subjects:
Atmospheric movements
Condensation
Nucleation
Ambient temperature change
balloon-borne
Condensation nuclei
Formation mechanism
Homogeneous nucleation
Meridional transport
Stratospheric aerosols
Trajectory analysis
Measurements
Arctic Oscillation
balloon observation
latitude
stratosphere
volcanic eruption
Antarctica
East Antarctica
Laramie
McMurdo Station
United States
Wyoming
Engineering
Antarctic
Arctic
The Antarctic
Antarc*
Online Access:https://hdl.handle.net/20.500.11919/666
https://doi.org/10.1002/2013JD019710
Description
Summary:©2013. The Authors. Balloon-borne stratospheric condensation nuclei (CN) measurements have been made from McMurdo Station, Antarctica (78°S), 1986-2010, and from Laramie, Wyoming (41°N), 1982 to the present. In the Antarctic region, the measurements show the formation of a layer of enhanced concentrations of stratospheric CN, between 21 and 27 km, around mid-August, reaching its maximum extent between September and early October. CN concentrations increase from backgrounds of 10-20 cm-3 to over 100 cm-3 in the layer. In the northern midlatitudes, the measurements show a quasi-annual and smaller layer of enhanced CN concentrations between 25 and 31 km in late winter and early spring. In the quasi-annual layers, CN concentrations increase from backgrounds of 1-10 cm-3 to over 20 cm-3. Volcanic eruptions appear to enhance the CN layers observed over Laramie and McMurdo. The Arctic Oscillation generally correlates with the magnitude of the Laramie CN layer, suggesting the importance of meridional transport. Volatility measurements and nucleation modeling support a sulfuric acid and water composition and binary homogeneous nucleation as the likely CN formation mechanism in both locations. Bimonthly measurements above Laramie support coagulation as the main reason for the dissipation of the CN layer. Air parcel trajectory modeling confirms that the CN layer forms locally to McMurdo and that it is related to solar exposure, while above Laramie trajectory analysis indicates that Arctic conditions and ambient temperature changes during northerly transport impact the magnitude of the CN layer above Laramie. Key points: Condensation nuclei measurements in the stratosphere are presented Condensation nuclei layers exist in the high and midlatitude stratosphere; The formation and volatility of condensation nuclei layers are characterized.

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