24 citations as recorded by crossref.

1. Next-generation ice-nucleating particle sampling on board aircraft: characterization of the High-volume flow aERosol particle filter sAmpler (HERA) S. Grawe et al.
2. Realistic representation of mixed-phase clouds increases projected climate warming S. Hofer et al.
3. Annual cycle of aerosol properties over the central Arctic during MOSAiC 2019–2020 – light-extinction, CCN, and INP levels from the boundary layer to the tropopause A. Ansmann et al.
4. An improved Freezing Ice Nucleation Detection Analyzer (FINDA) for droplet immersion freezing measurement K. Wang et al.
5. A comprehensive characterisation of natural aerosol sources in the high Arctic during the onset of sea ice melt G. Freitas et al.
6. Ice-nucleating particles at Ny-Ålesund: a study of condensation freezing by the Dynamic Filter Processing Chamber M. Rinaldi et al.
7. High ice-nucleating particle concentrations associated with Arctic haze in springtime cold-air outbreaks E. Raif et al.
8. Thirty years of arctic primary marine organic aerosols: patterns, seasonal dynamics, and trends (1990–2019) A. Leon-Marcos et al.
9. Surface warming in Svalbard may have led to increases in highly active ice-nucleating particles Y. Tobo et al.
10. Contribution of fluorescent primary biological aerosol particles to low-level Arctic cloud residuals G. Pereira Freitas et al.
11. The Puy de Dôme ICe Nucleation Intercomparison Campaign (PICNIC): comparison between online and offline methods in ambient air L. Lacher et al.
12. Transport of continental particulate over the Labrador Sea and entrainment are important pathways for glaciation of remote marine clouds H. Coe et al.
13. Bio-climatic factors drive spectral vegetation changes in Greenland T. Silva et al.
14. Bioaerosols as indicators of central Arctic ice nucleating particle sources K. Barry et al.
15. Polar primary aerosols across the ocean-sea ice-snow-atmosphere interface: From sources to impacts J. Creamean et al.
16. Regionally sourced bioaerosols drive high-temperature ice nucleating particles in the Arctic G. Pereira Freitas et al.
17. Ice-nucleating particle concentration impacts cloud properties over Dronning Maud Land, East Antarctica, in COSMO-CLM2 F. Sauerland et al.
18. Gaps in our understanding of ice-nucleating particle sources exposed by global simulation of the UK Earth System Model R. Herbert et al.
19. Increasing Arctic dust suppresses the reduction of ice nucleation in the Arctic lower troposphere by warming H. Matsui et al.
20. Ice-nucleating particle depletion in the wintertime boundary layer in the pre-Alpine region during stratus cloud conditions K. Ohneiser et al.
21. Simulations of primary and secondary ice production during an Arctic mixed-phase cloud case from the Ny-Ålesund Aerosol Cloud Experiment (NASCENT) campaign B. Schäfer et al.
22. Using a region-specific ice-nucleating particle parameterization improves the representation of Arctic clouds in a global climate model A. Gjelsvik et al.
23. Linking biogenic high-temperature ice nucleating particles in Arctic soils and streams to their microbial producers L. Jensen et al.
24. A Novel Mechanism of Sea-Surface Microlayer Formation Driven by Terrestrial Runoff: A Source of Ice Nucleating Particles in Arctic Coastal Environments J. Schmidt et al.