I am a project research assistant in meteorology affiliated with the National Taiwan University. I am broadly interested in storm physics, precipitation processes, emphasizing on the multiscale interaction between storms and environment leading to extreme precipitation. In all of my research projects, I tried to combine a love of field work and numerical modeling to illustrate hidden relationships in the data. The main observational tool I used is polarimetric radars, which can be used to infer kinematic and microphysical processes in precipitating storms. Physical inferences gleaned from observations can be further tested with physical process limiting modeling. A recent collaboration with Ming-Jen Yang (NTU) and Wen-Chau Lee (NCAR) on the development of a new radar observable to reveal information on difficult-to-observe storm thermodynamics, exemplify my research approach well. Lately, I have been increasingly interested in leveraging statistical methods and big data on the interaction between weather and climate.
Publications
Frederick Iat-Hin Tam, Ming-Jen Yang, Wen-Chau Lee
In preparation, 2021
Frederick Iat-Hin Tam, Ming-Jen Yang, Wen-Chau Lee
In revision, Journal of Geophysical Research: Atmospheres, 2021
Sensitivity of Simulated Nocturnal Convective Systems to Graupel Sedimentation Characteristics
Frederick Iat-Hin Tam, Ming-Jen Yang
Preprints. 2019 Conference of Weather Analysis and Forecast, Taiwan Geoscience Assembly (TGA), 2019 May
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Projects
Precipitation from nocturnal MCSs is critical to the agricultural industry in the U. S. Great Plains. In this project, a combination of observation, reanalysis, and modeling was used to understand why some storms sustain longer than others.
Diagnose hard-to-observe storm characteristics with radar observables (2020-2021)
Storm kinematic/thermodynamic characteristics are important but often hard to observe. In this project, we analyzed 74.5 hours of radar data to explore the feasibility of using a novel radar observable to diagnose the hard-to-observes.
Evaluating model depiction of boundary layer diurnal cycles over a subtropical island (2021-)
A validating study to test what WRF configurations best emulate observed BL evolution. My task in this project is to develop a simple algorithm that identifies BL height from lidar data.
In early June 2021, we acquired high temporal resolution radiosonde measurements (even under soft lock-down!) on the pre- and post-storm environment on two shear-paralleled MCSs in near-saturated environment.
Pages
Here are some courses that I served as the teaching assistant during and after my MS career