The Ice Particle and Aggregate Simulator (IPAS). Part I: Extracting Dimensional Properties of Ice–Ice Aggregates for Microphysical Parameterization

Aggregation, the process by which two or more ice particles attach to each other, is typically observed in clouds that span a range of temperatures and is influenced by the crystal shape (habit). In this study, the resulting characteristics of ice–ice two-monomer aggregation is investigated, which i...

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Bibliographic Details
Published in:Journal of the atmospheric sciences 2019-06, Vol.76 (6), p.1661-1676
Main Authors: Przybylo, Vanessa M., Sulia, Kara J., Schmitt, Carl G., Lebo, Zachary J., May, William C.
Format: Article
Language:English
Subjects:
Agglomeration
Aggregates
Aggregation
Aspect ratio
cloud parameterizations
cloud resolving models
Clouds
Collection
Computer simulation
Contact angle
Crystal structure
Crystal surfaces
Efficiency
ENVIRONMENTAL SCIENCES
Experiments
Falling
Habits
Ice
Ice crystals
Ice particles
Laboratories
Mass distribution
meteorology & atmospheric sciences
Monomers
Orientation
Parameterization
Precipitation
Prisms
Properties
Properties (attributes)
Ratios
Sedimentation & deposition
Shape
Simulators
Temperature
Temperature range
Three dimensional models
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Summary:Aggregation, the process by which two or more ice particles attach to each other, is typically observed in clouds that span a range of temperatures and is influenced by the crystal shape (habit). In this study, the resulting characteristics of ice–ice two-monomer aggregation is investigated, which is expected to improve microphysical parameterizations through more precise aggregate characteristics and in turn better predict the rate of aggregation and snow development. A systematic way to determine the aspect ratio of the aggregate was developed, which takes into account the expected falling orientations, overlap of each monomer, and any contact angle that may form through so-called constrained randomization. Distributions were used to obtain the most frequent aspect ratio, major axis, and minor axis of aggregated particles with respect to the monomer aspect ratio. Simulations were completed using the Ice Particle and Aggregate Simulator (IPAS), a model that uses predefined three-dimensional geometries, (e.g., hexagonal prisms) to simulate ice crystal aggregation and allows for variation in crystal size, shape, number, and falling orientation. In this study, after collection in a theoretical grid space, detailed information is extracted from the particles to determine the properties of aggregates. It was found that almost all monomer aspect ratios aggregate to less extreme aggregate aspect ratios at nearly the same rate. Newly formed aggregate properties are amenable to implementation into more sophisticated bulk microphysical models designed to predict and evolve particle properties, which is crucial in realistically evolving cloud ice mass distribution and for representing the collection process.
ISSN:0022-4928
1520-0469
DOI:10.1175/JAS-D-18-0187.1