| The Arctic cloud puzzle: Using ACLOUD/PASCAL multiplatform observations to unravel the role of clouds and aerosol particles in Arctic amplification M Wendisch, A Macke, A Ehrlich, C Lüpkes, M Mech, D Chechin, ... Bulletin of the American Meteorological Society 100 (5), 841-871, 2019 | 195* | 2019 |
| EURECA B Stevens, S Bony, D Farrell, F Ament, A Blyth, C Fairall, J Karstensen, ... Earth System Science Data 13 (8), 4067-4119, 2021 | 125 | 2021 |
| An underestimated negative cloud feedback from cloud lifetime changes J Mülmenstädt, M Salzmann, JE Kay, MD Zelinka, PL Ma, C Nam, ... Nature Climate Change 11 (6), 508-513, 2021 | 82 | 2021 |
| Atmospheric and surface processes, and feedback mechanisms determining Arctic amplification: A review of first results and prospects of the (AC) 3 project M Wendisch, M Brückner, S Crewell, A Ehrlich, J Notholt, C Lüpkes, ... Bulletin of the American Meteorological Society 104 (1), E208-E242, 2023 | 63 | 2023 |
| Reducing the aerosol forcing uncertainty using observational constraints on warm rain processes J Mülmenstädt, C Nam, M Salzmann, J Kretzschmar, TS L’Ecuyer, ... Science Advances 6 (22), eaaz6433, 2020 | 50 | 2020 |
| Detection and attribution of aerosol–cloud interactions in large-domain large-eddy simulations with the ICOsahedral Non-hydrostatic model M Costa-Surós, O Sourdeval, C Acquistapace, H Baars, ... Atmospheric chemistry and physics 20 (9), 5657-5678, 2020 | 29 | 2020 |
| Comment on “Rethinking the Lower Bound on Aerosol Radiative Forcing” J Kretzschmar, M Salzmann, J Mülmenstädt, O Boucher, J Quaas Journal of Climate 30 (16), 6579-6584, 2017 | 27 | 2017 |
| Employing airborne radiation and cloud microphysics observations to improve cloud representation in ICON at kilometer-scale resolution in the Arctic J Kretzschmar, J Stapf, D Klocke, M Wendisch, J Quaas Atmospheric Chemistry and Physics 20 (21), 13145-13165, 2020 | 23 | 2020 |
| Arctic clouds in ECHAM6 and their sensitivity to cloud microphysics and surface fluxes J Kretzschmar, M Salzmann, J Mülmenstädt, J Quaas Atmospheric Chemistry and Physics 19 (16), 10571-10589, 2019 | 16* | 2019 |
| Impact of Holuhraun volcano aerosols on clouds in cloud-system-resolving simulations M Haghighatnasab, J Kretzschmar, K Block, J Quaas Atmospheric Chemistry and Physics 22 (13), 8457-8472, 2022 | 12 | 2022 |
| Projecting stratocumulus transitions on the albedo—Cloud fraction relationship reveals linearity of albedo to droplet concentrations T Goren, G Feingold, E Gryspeerdt, J Kazil, J Kretzschmar, H Jia, J Quaas Geophysical Research Letters 49 (20), e2022GL101169, 2022 | 10 | 2022 |
| Subgrid-scale variability in clear-sky relative humidity and forcing by aerosol–radiation interactions in an atmosphere model P Petersik, M Salzmann, J Kretzschmar, R Cherian, D Mewes, J Quaas Atmospheric Chemistry and Physics 18 (12), 8589-8599, 2018 | 8 | 2018 |
| Spatial aggregation of satellite observations leads to an overestimation of the radiative forcing due to aerosol‐cloud interactions T Goren, O Sourdeval, J Kretzschmar, J Quaas Geophysical Research Letters 50 (18), e2023GL105282, 2023 | 7 | 2023 |
| Northern hemisphere regional climate engineering can trigger Arctic warming D Sudhakar, J Quaas, J Kretzschmar AGU Fall Meeting Abstracts 2018, GC31H-1345, 2018 | | 2018 |
