about
Mechanisms controlling water vapor in the lower stratosphere: “A tale of two stratospheres”Can ozone depletion and global warming interact to produce rapid climate change?Transport in time-dependent dynamical systems: finite-time coherent sets.Decadal evolution of the Antarctic ozone hole.Model evaluation of CO2and SF6in the extratropical UT/LS regionComparison of satellite ozone observations in coincident air masses in early November 1994Multi-year comparisons of ground-based and space-borne Fourier transform spectrometers in the high Arctic between 2006 and 2013Persistence of the lower stratospheric polar vorticesComparisons between measurements and models of Antarctic ozone lossBulk properties of isentropic mixing into the tropics in the lower stratosphereDevelopment of the Antarctic ozone holeMeasurements of the NOy-N2O correlation in the lower stratosphere: Latitudinal and seasonal changes and model comparisonsSpread of denitrification from 1987 Antarctic and 1988–1989 Arctic stratospheric vorticesComparison of empirically derived ozone losses in the Arctic vortexLidar measurements during Aerosols99Photochemical ozone loss in the Arctic as determined by MSX/UVISI stellar occultation observations during the 1999/2000 winterTransport out of the Antarctic polar vortex from a three-dimensional transport modelThe climatological mean atmospheric transport under weakened Atlantic thermohaline circulation climate scenarioOzone depletion in the late winter lower Arctic stratosphere: Observations and model resultsTracer-based determination of vortex descent in the 1999/2000 Arctic winterOzone measurements during the Airborne Polar Experiment: Aircraft instrument validation, isentropic trends, and hemispheric fields prior to the 1997 Arctic ozone depletionPolar stratospheric clouds climatology over Dumont d'Urville between 1989 and 1993 and the influence of volcanic aerosols on their formationChlorine deactivation in the lower stratospheric polar regions during late winter: Results from UARSQuantification of the transport of chemically activated air from the northern hemisphere polar vortexAircraft observations of rapid meridional transport from the tropical tropopause layer into the lowermost stratosphere: Implications for midlatitude ozoneEvolution of inorganic chlorine partitioning in the Arctic polar vortexDefining the polar vortex edge from an N2O:potential temperature correlationChemical definition of the mesospheric polar vortexA multi tracer analysis of thermosphere to stratosphere descent triggered by the 2013 Stratospheric Sudden WarmingBreakdown of potential vorticity–based equivalent latitude as a vortex-centered coordinate in the polar winter mesosphereLow-ozone pockets observed by EOS-MLSPOAM II ozone observations in the Antarctic ozone hole in 1994, 1995, and 1996Tropical mixing barriers in the lower stratosphere in the Geophysical Fluid Dynamics Laboratory SKYHI modelA climatology of stratospheric polar vortices and anticyclonesTropical aerosol in the Aleutian HighSeasonal ozone variations in the isentropic layer between 330 and 380 K as observed by SAGE II: Implications of extratropical cross-tropopause transportThree-dimensional simulation of the influence of a cutoff low on the distribution of northern hemisphere processed air in late January 1992Tracer evolution in winds generated by a global spectral mechanistic modelTracer exchange between tropics and middle latitudesLagrangian flow in the middle atmosphere
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P2860
description
im Januar 1992 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в 1992
@uk
name
The structure of the polar vortex
@en
The structure of the polar vortex
@nl
type
label
The structure of the polar vortex
@en
The structure of the polar vortex
@nl
prefLabel
The structure of the polar vortex
@en
The structure of the polar vortex
@nl
P2093
P2860
P356
P1476
The structure of the polar vortex
@en
P2093
Joan E. Rosenfield
Leslie R. Lait
Mark R. Schoeberl
Paul A. Newman
P2860
P356
10.1029/91JD02168
P407
P577
1992-01-01T00:00:00Z