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--- publications [2024/05/01 07:34] – [2024] neggers
+++ publications [2025/06/26 13:33] (current) – [2025] neggers
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 ====== Publications ======
+===== 2025 =====
+Burchart. Y., B. Pospichal and R. A. J. Neggers, 2025: Confronting Large-Eddy Simulations with Stereo Camera Data by means of reconstructed hemispheric Cloud Size Distributions. //JAMES, [[https://doi.org/10.1029/2024MS004804]]//
+Neggers, R. A. J., J. Chylik and N. Schnierstein, 2025: The entrainment efficiency of persistent Arctic mixed-phase clouds as inferred from daily large-eddy simulations during the MOSAiC drift. //J. Atmos. Sci.//, [[https://doi.org/10.1175/JAS-D-24-0188.1]]
+Raghunathan, G. N., P. Blossey, S. Boeing, L. Denby, S. Ghazayel, T. Heus , J. Kazil and R. A J. Neggers: Flower-type organized trade-wind cumulus: A multi-day Lagrangian Large Eddy Simulation intercomparison study. //In review for publication in JAMES, May 2025.//
 ===== 2024 =====
-Burchart, Y., C. Beekmans and R. A. J. Neggers (2024): A Stereo Camera Network simulator for Large-Eddy Simulations of continental Shallow Cumulus clouds based on three-dimensional Path-Tracing. J. Atmos. Modeling Earth Syst., https://doi.org/10.1029/2023MS003797
+Burchart, Y., C. Beekmans and R. A. J. Neggers (2024): A Stereo Camera Network simulator for Large-Eddy Simulations of continental Shallow Cumulus clouds based on three-dimensional Path-Tracing. //J. Atmos. Modeling Earth Syst.//, https://doi.org/10.1029/2023MS003797
 Kiszler, T., Ori, D., and Schemann, V. (2023): Microphysical processes involving the vapour phase dominate in simulated low-level Arctic clouds, EGUsphere [preprint], [[https://doi.org/10.5194/egusphere-2023-2986]].
-Schnierstein et al.: Standardized daily high-resolution large-eddy simulations of the Arctic boundary layer and clouds during the complete MOSAiC drift. SUbmitted to JAMES, https://essopenarchive.org/doi/full/10.22541/essoar.171033230.00246941
+Paulus, F. M., M. Karalis, G. George, G. Svensson, M. Wendisch, and R. A. J. Neggers (2024): Airborne measurements of mesoscale divergence at high latitudes during HALO-(AC)3. //J. Atmos. Sci.//, [[https://doi.org/10.1175/JAS-D-24-0034.1]]
+Schnierstein, N., J. Chylik, M. D. Shupe and R. A. J. Neggers: Standardized daily high-resolution large-eddy simulations of the Arctic boundary layer and clouds during the complete MOSAiC drift. //JAMES//, [[https://doi.org/10.1029/2024MS004296]]
+Walbröl, A., Michaelis, J., Becker, S., Dorff, H., Gorodetskaya, I., Kirbus, B., Lauer, M., Maherndl, N., Maturilli, M., Mayer, J., Müller, H., Neggers, R. A. J., Paulus, F. M., Röttenbacher, J., Rückert, J. E., Schirmacher, I., Slättberg, N., Ehrlich, A., Wendisch, M., and Crewell, S.: Environmental conditions in the North Atlantic sector of the Arctic during the HALO–(AC)³ campaign, EGUsphere [preprint], https://doi.org/10.5194/egusphere-2023-668, 2023.
 Wendisch et al., 2024: Overview: Quasi-Lagrangian observations of Arctic air mass transformations – Introduction and initial results of the HALO–(AC)3 aircraft campaign. preprint,
 https://doi.org/10.5194/egusphere-2024-783
 ===== 2023 =====