66 citations as recorded by crossref.

1. A general climate model simulation of the aerosol radiative effects of the Laacher See eruption (10,900 B.C.) H. Graf & C. Timmreck
2. Impact of stratospheric dynamics and chemistry on northern hemisphere midlatitude ozone loss
3. Critique of the tracer‐tracer correlation technique and its potential to analyze polar ozone loss in chemistry‐climate models C. Lemmen et al.
4. Klimafaktor Luftfahrt R. Sausen et al.
5. Multiscale modeling of air pollutants dynamics in the northwestern Mediterranean basin during a typical summertime episode P. Jiménez et al.
6. Hemispheric ozone variability indices derived from satellite observations and comparison to a coupled chemistry-climate model T. Erbertseder et al.
7. A new interactive chemistry‐climate model: 2. Sensitivity of the middle atmosphere to ozone depletion and increase in greenhouse gases and implications for recent stratospheric cooling E. Manzini et al.
8. Impact of future subsonic aircraft NOx emissions on the atmospheric composition V. Grewe et al.
9. Impact of prescribed SSTs on climatologies and long-term trends in CCM simulations H. Garny et al.
10. Global long-term monitoring of the ozone layer – a prerequisite for predictions D. Loyola et al.
11. Three‐dimensional chemical model simulations of the ozone layer: 1979–2015 J. Austin et al.
12. On‐line simulations of passive chemical tracers in the University of California, Los Angeles, atmospheric general circulation model: 1. CFC‐11 and CFC‐12 M. Gupta et al.
13. Comparison of measured and modeled ozone above McMurdo Station, Antarctica, 1989–2003, during austral winter/spring J. Mercer et al.
14. Aviation‐induced radiative forcing and surface temperature change in dependency of the emission altitude C. Frömming et al.
15. Chemical ozone loss in a chemistry‐climate model from 1960 to 1999 C. Lemmen et al.
16. The 27-day solar rotational cycle in the Freie Universität Berlin Climate Middle Atmosphere Model with interactive chemistry (FUB CMAM CHEM) J. Grenfell et al.
17. A fast stratospheric chemistry solver: the E4CHEM submodel for the atmospheric chemistry global circulation model EMAC A. Baumgaertner et al.
18. Relationship between North Atlantic Oscillation changes and stratospheric ozone recovery in the Northern Hemisphere in a chemistry‐climate model C. Schnadt & M. Dameris
19. Tropospheric chemistry in the Integrated Forecasting System of ECMWF J. Flemming et al.
20. The influence of the OH + NO2 + M reaction on the NOy, partitioning in the late Arctic winter 1992/1993 as studied with KASIMA R. Ruhnke et al.
21. Origin and variability of upper tropospheric nitrogen oxides and ozone at northern mid-latitudes V. Grewe et al.
22. Multiannual simulations with a three‐dimensional chemical transport model M. Chipperfield
23. Review of the formulation of present‐generation stratospheric chemistry‐climate models and associated external forcings O. Morgenstern et al.
24. Impact of dynamically induced ozone mini-hole events on PSC formation and chemical ozone destruction A. Stenke & V. Grewe
25. Dynamic-chemical coupling of the upper troposphere and lower stratosphere region V. Grewe et al.
26. Three-dimensional simulations of ozone in the stratosphere and comparison with UARS data E. Rozanov et al.
27. Long-range prediction and the stratosphere A. Scaife et al.
28. The UIUC three‐dimensional stratospheric chemical transport model: Description and evaluation of the simulated source gases and ozone E. Rozanov et al.
29. Net effect of the QBO in a chemistry climate model H. Punge & M. Giorgetta
30. The impact of horizontal transport on the chemical composition in the tropopause region: lightning NO and streamers V. Grewe et al.
31. European scientific assessment of the atmospheric effects of aircraft emissions G. Brasseur et al.
32. Quantifying the contributions of individual NOx sources to the trend in ozone radiative forcing K. Dahlmann et al.
33. Future changes of the atmospheric composition and the impact of climate change V. Grewe et al.
34. Implications of Lagrangian transport for simulations with a coupled chemistry-climate model A. Stenke et al.
35. Future UV radiation in Central Europe modelled from ozone scenarios J. Reuder et al.
36. Pollution from aircraft emissions in the North Atlantic flight corridor: Overview on the POLINAT projects U. Schumann et al.
37. Impact of ozone mini-holes on the heterogeneous destruction of stratospheric ozone A. Stenke & V. Grewe
38. The University of Illinois, Urbana‐Champaign three‐dimensional stratosphere‐troposphere general circulation model with interactive ozone photochemistry: Fifteen‐year control run climatology E. Rozanov et al.
39. Do climate models project changes in solar resources? I. Huber et al.
40. The summer–midwinter correlation in total ozone over North America and Europe for the period 1963–1997 J. Krzyścin et al.
41. Assessment of temperature, trace species, and ozone in chemistry‐climate model simulations of the recent past V. Eyring et al.
42. The atmospheric chemistry general circulation model ECHAM5/MESSy1: consistent simulation of ozone from the surface to the mesosphere P. Jöckel et al.
43. Three‐dimensional simulation of stratospheric background aerosol: First results of a multiannual general circulation model simulation C. Timmreck
44. Assessment of the future development of the ozone layer M. Dameris et al.
45. Attribution of ozone changes to dynamical and chemical processes in CCMs and CTMs H. Garny et al.
46. Implications of all season Arctic sea-ice anomalies on the stratosphere D. Cai et al.
47. Chemical reaction pathways affecting stratospheric and mesospheric ozone J. Grenfell et al.
48. Interactive chemistry in the Laboratoire de Météorologie Dynamique general circulation model: Description and background tropospheric chemistry evaluation D. Hauglustaine et al.
49. Stratospheric ozone in 3‐D models: A simple chemistry and the cross‐tropopause flux C. McLinden et al.
50. The leading variability mode of the coupled troposphere‐stratosphere winter circulation in different climate regimes J. Perlwitz et al.
51. Stratospheric and tropospheric response to enhanced solar UV radiation: A model study K. Tourpali et al.
52. Drivers of hemispheric differences in return dates of mid-latitude stratospheric ozone to historical levels H. Garny et al.
53. A global model tool for three‐dimensional multiyear stratospheric chemistry simulations: Model description and first results M. Rummukainen et al.
54. A new interactive chemistry‐climate model: 1. Present‐day climatology and interannual variability of the middle atmosphere using the model and 9 years of HALOE/UARS data B. Steil et al.
55. Transport of SF₆ and ¹⁴CO₂ in the atmospheric general circulation model ECHAM4 E. Kjellström et al.
56. AirClim: an efficient tool for climate evaluation of aircraft technology V. Grewe & A. Stenke
57. The impact of greenhouse gases and halogenated species on future solar UV radiation doses P. Taalas et al.
58. Response of middle atmosphere chemistry and dynamics to volcanically elevated sulfate aerosol: Three‐dimensional coupled model simulations J. Al‐Saadi et al.
59. Simulation of the climate impact of Mt. Pinatubo eruption using ECHAM5 – Part 2: Sensitivity to the phase of the QBO and ENSO M. Thomas et al.
60. Consistent simulation of bromine chemistry from the marine boundary layer to the stratosphere – Part 2: Bromocarbons A. Kerkweg et al.
61. Dynamically Forced Increase of Tropical Upwelling in the Lower Stratosphere H. Garny et al.
62. A one and half year interactive MA/ECHAM4 simulation of Mount Pinatubo Aerosol C. Timmreck et al.
63. The contribution of ocean‐leaving DMS to the global atmospheric burdens of DMS, MSA, SO2, and NSS SO4= M. Gondwe et al.
64. Effects of the quasi‐biennial oscillation on low‐latitude transport in the stratosphere derived from trajectory calculations H. Punge et al.
65. Radiative forcing from particle emissions by future supersonic aircraft G. Pitari et al.
66. Impact of aircraft NOx emissions on tropospheric and stratospheric ozone. part II M. Dameris et al.