66 citations as recorded by crossref.

1. Cirrus Cloud Properties as Seen by the CALIPSO Satellite and ECHAM-HAM Global Climate Model B. Gasparini et al.
2. Impacts of ice-nucleating particles on cirrus clouds and radiation derived from global model simulations with MADE3 in EMAC C. Beer et al.
3. Cirrus formation regimes – data-driven identification and quantification of mineral dust effect K. Jeggle et al.
4. A combined observational and modelling approach to evaluate aerosol–cirrus interactions at high and mid-latitudes E. De La Torre Castro et al.
5. Is increasing ice crystal sedimentation velocity in geoengineering simulations a good proxy for cirrus cloud seeding? B. Gasparini et al.
6. Radiative forcing of anthropogenic aerosols on cirrus clouds using a hybrid ice nucleation scheme J. Zhu & J. Penner
7. Impact of aerosols on ice crystal size B. Zhao et al.
8. Aerosol–cloud–radiation interaction during Saharan dust episodes: the dusty cirrus puzzle A. Seifert et al.
9. Effects of thermodynamics, dynamics and aerosols on cirrus clouds based on in situ observations and NCAR CAM6 R. Patnaude et al.
10. Global aerosol modeling with MADE3 (v3.0) in EMAC (based on v2.53): model description and evaluation J. Kaiser et al.
11. Developing a Cloud Scheme With Prognostic Cloud Fraction and Two Moment Microphysics for ECHAM‐HAM S. Muench & U. Lohmann
12. Overview of Ice Nucleating Particles Z. Kanji et al.
13. Constraining Precipitation Susceptibility of Warm-, Ice-, and Mixed-Phase Clouds with Microphysical Equations F. Glassmeier & U. Lohmann
14. What controls the low ice number concentration in the upper troposphere? C. Zhou et al.
15. Remote sensing ice supersaturation inside and near cirrus clouds: a case study in the subtropics C. Hoareau et al.
16. Cirrus Clouds and Their Response to Anthropogenic Activities B. Kärcher
17. Effect of cloud‐scale vertical velocity on the contribution of homogeneous nucleation to cirrus formation and radiative forcing X. Shi & X. Liu
18. Implementation of a comprehensive ice crystal formation parameterization for cirrus and mixed-phase clouds in the EMAC model (based on MESSy 2.53) S. Bacer et al.
19. Bounding Global Aerosol Radiative Forcing of Climate Change N. Bellouin et al.
20. Aerosol effects on cirrus through ice nucleation in the Community Atmosphere Model CAM5 with a statistical cirrus scheme M. Wang et al.
21. The Role of Mineral Dust Aerosol Particles in Aviation Soot‐Cirrus Interactions B. Kärcher et al.
22. AIRTRAC v2.0: a Lagrangian aerosol tagging submodel for the analysis of aviation SO4 transport patterns J. Maruhashi et al.
23. Dominant role of mineral dust in cirrus cloud formation revealed by global-scale measurements K. Froyd et al.
24. Does prognostic seeding along flight tracks produce the desired effects of cirrus cloud thinning? C. Tully et al.
25. Aviation soot interactions with natural cirrus clouds are unlikely to have a significant impact on global climate M. Righi et al.
26. Ice-nucleating particle versus ice crystal number concentrationin altocumulus and cirrus layers embedded in Saharan dust:a closure study A. Ansmann et al.
27. Addressing Complexity in Global Aerosol Climate Model Cloud Microphysics U. Proske et al.
28. Assessing predicted cirrus ice properties between two deterministic ice formation parameterizations C. Tully et al.
29. Global Radiative Impacts of Mineral Dust Perturbations Through Stratiform Clouds Z. McGraw et al.
30. Modelling of mineral dust for interglacial and glacial climate conditions with a focus on Antarctica N. Sudarchikova et al.
31. A global climatology of ice-nucleating particles under cirrus conditions derived from model simulations with MADE3 in EMAC C. Beer et al.
32. Study on the Parameters of Ice Clouds Based on 1.5 µm Micropulse Polarization Lidar Y. Li et al.
33. Underestimated inhibition of cloud water by dust aerosols in the Yangtze River Delta T. Xu et al.
34. Saharan dust and cirrus clouds: Dominating indirect impact of dust events on photovoltaic energy generation in Hungar y (2019–2024) G. Varga et al.
35. Pore condensation and freezing is responsible for ice formation below water saturation for porous particles R. David et al.
36. Mitigating the Climate Impact from Aviation: Achievements and Results of the DLR WeCare Project V. Grewe et al.
37. The global impact of the transport sectors on the atmospheric aerosol and the resulting climate effects under the Shared Socioeconomic Pathways (SSPs) M. Righi et al.
38. Impact of wildfire smoke on Arctic cirrus formation – Part 2: Simulation of MOSAiC 2019–2020 cases A. Ansmann et al.
39. To what extent can cirrus cloud seeding counteract global warming? B. Gasparini et al.
40. Trans-Pacific Saharan dust recorded in Mount Logan ice core K. Nagashima et al.
41. A Process Study on Thinning of Arctic Winter Cirrus Clouds With High‐Resolution ICON‐ART Simulations S. Gruber et al.
42. Cirrus Clouds A. Heymsfield et al.
43. Cold cloud microphysical process rates in a global chemistry–climate model S. Bacer et al.
44. Sensitivity of dust event simulation to dust emission schemes and meteorological forcing datasets in the Belt and Road regions: A case study N. Ren et al.
45. A Parameterization of Cirrus Cloud Formation: Revisiting Competing Ice Nucleation B. Kärcher
46. The Relationship of Aerosol Properties and Ice‐Nucleating Particle Concentrations in Beijing Y. Ren et al.
47. Ice Nucleation of Cirrus Clouds Related to the Transported Dust Layer Observed by Ground-Based Lidars over Wuhan, China Y. He et al.
48. Future warming exacerbated by aged-soot effect on cloud formation U. Lohmann et al.
49. Anthropogenic Aerosol Indirect Effects in Cirrus Clouds J. Penner et al.
50. Influence of volcanic eruptions on midlatitude upper tropospheric aerosol and consequences for cirrus clouds J. Friberg et al.
51. Coupling aerosols to (cirrus) clouds in the global EMAC-MADE3 aerosol–climate model M. Righi et al.
52. Technical note: Fundamental aspects of ice nucleation via pore condensation and freezing including Laplace pressure and growth into macroscopic ice C. Marcolli
53. Exploring the uncertainties in the aviation soot–cirrus effect M. Righi et al.
54. Why cirrus cloud seeding cannot substantially cool the planet B. Gasparini & U. Lohmann
55. Additional global climate cooling by clouds due to ice crystal complexity E. Järvinen et al.
56. Effects of pre-existing ice crystals on cirrus clouds and comparison between different ice nucleation parameterizations with the Community Atmosphere Model (CAM5) X. Shi et al.
57. Prognostic precipitation with three liquid water classes in the ECHAM5–HAM GCM V. Sant et al.
58. Aerosol Indirect Effects on Cirrus Clouds Based on Global Aircraft Observations R. Patnaude & M. Diao
59. Global dust distribution from improved thin dust layer detection using A‐train satellite lidar observations T. Luo et al.
60. Dust effects on mixed-phase clouds and precipitation during a super dust storm over northern China R. Luo et al.
61. The global aerosol–climate model ECHAM6.3–HAM2.3 – Part 2: Cloud evaluation, aerosol radiative forcing, and climate sensitivity D. Neubauer et al.
62. The Impact of Mesoscale Gravity Waves on Homogeneous Ice Nucleation in Cirrus Clouds B. Kärcher et al.
63. Cirrus cloud thinning using a more physically based ice microphysics scheme in the ECHAM-HAM general circulation model C. Tully et al.
64. An aerosol classification scheme for global simulations using the K-means machine learning method J. Li et al.
65. Technical note: Identification of two ice-nucleating regimes for dust-related cirrus clouds based on the relationship between number concentrations of ice-nucleating particles and ice crystals Y. He et al.
66. Understanding cirrus clouds using explainable machine learning K. Jeggle et al.