A Concept of a Convection–Cloud Chamber to Study Aerosol–Cloud–Drizzle Interactions

Authors

• Raymond Shaw, Michigan Technological UniversityFollow
• Mikhail Ovchinnikov, Pacific Northwest National Laboratory
• Arthur J. Sedlacek III, Brookhaven National Laboratory
• Fan Yang, Brookhaven National Laboratory
• Jesse C. Anderson, Michigan Technological UniversityFollow
• Zaid Bakri, Michigan Technological UniversityFollow
• Will Cantrell, Michigan Technological UniversityFollow
• Hamed F. Sadi, Michigan Technological UniversityFollow
• Claudio Mazzoleni, Michigan Technological UniversityFollow
• Yangze Ren, Michigan Technological UniversityFollow
• Grant T. Schlaff, Michigan Technological UniversityFollow
• Suryadev Pratap Singh, Michigan Technological UniversityFollow
• Lois Thomas, Michigan Technological University
• Jae Min Yeom, Michigan Technological UniversityFollow
• et al.

Document Type

Article

Publication Date

6-1-2026

Department

Department of Physics

Abstract

Understanding and quantifying the full chain of processes from aerosol activation
to drizzle formation, and the associated feedbacks to the aerosol chemical and physical proper-ties, all within a turbulent cloud are some of the toughest challenges in atmospheric chemistry and physics and are keys to the cloud–precipitation puzzle. This paper describes a concept fora new type of research facility consisting of a cloud chamber plus associated instrumentation
and computational models, to explore aerosol–cloud interactions and processing, cloud optical properties, entrainment–cloud interactions, and quantitative assessment of drizzle onset. The envisioned design is for a 3 m × 3 m × 9 m chamber, such that the height is sufficient to achieve long lifetimes for aerosol processing and for significant drizzle growth by collision and coalescence.
A suite of computational tools for simulating microphysical properties in the chamber provides a digital twin for designing the chamber and a range of example experiments. Theory and test results from novel remote sensing systems for exploring chemical and physical interactions and evolution of aerosols, cloud droplets, and drizzle within turbulent clouds are described. Testing of technology needed for the operation of a large-volume chamber, including aerosol generation methods and novel materials for water vapor boundary conditions, is described. Simulations suggest that spatially uniform turbulence and microphysical properties can be sustained in a steady state, with reasonable aerosol and water vapor fluxes, and that substantial drizzle can be produced through collision and coalescence of cloud droplets. Remaining challenges for more detailed engineering design and a discussion of possible first-light experiments are described.

Publication Title

Bulletin of the American Meteorological Society

Recommended Citation

Shaw, R., Ovchinnikov, M., Sedlacek, A. J., Yang, F., Anderson, J., Bakri, Z., Cantrell, W., Sadi, H. F., Mazzoleni, C., Ren, Y., Schlaff, G., Singh, S. P., Thomas, L., Yeom, J., & et al. (2026). A Concept of a Convection–Cloud Chamber to Study Aerosol–Cloud–Drizzle Interactions. Bulletin of the American Meteorological Society, 107(6), E1226-E1247. http://doi.org/10.1175/BAMS-D-25-0113.1
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p2/2706