The Impact of Assimilating GNSS-RO Observations on HAFS Tropical Cyclone Forecasts from the 2022 Atlantic Hurricane Season

Global Navigation Satellite System radio occultation (GNSS-RO) data have become an essential part of observational assimilation in numerical weather prediction (NWP) models due to their high accuracy and precision, insensi-tivity to clouds and precipitation, high vertical resolution, and a considerable increase in sampling density in recent years. Their impact has been demonstrated in many global models, as well as in several regional models. In this study, we show the impact of assimilating GNSS-RO bending angle (BA) observations on 10 tropical cyclone (TC) forecasts from the 2022 Atlantic hurricane season using the Hurricane Analysis and Forecast System (HAFS) model. Our evaluation shows that track forecasts are improved considerably (;15%–20%) after assimilating RO BAs, mainly through global model forecasts as initial and boundary conditions for HAFS, and these improvements are especially evident at longer forecast lead times. A case study of Hurricane Ian, a category 5 hurricane, which made landfall along the western Florida coast, showed greatly improved landfall prediction 3–5 days before landfall after assimilating RO BAs due to improved forecasts of the synoptic-scale steering flow over the region. Further study after adding many additional commercial RO profiles for assimilation through the Radio Occultation Modeling Experiment (ROMEX) showed 25%–30% improvements to TC intensity forecasts at longer lead times, albeit utilizing fewer TCs in the sample. For example, Hurricane Ian showed HAFS accurately forecasting maximum wind speeds, including its rapid intensification, 2–4 days in advance due to the improved representation of midlevel moisture in the vicinity of Ian. These results emphasize the benefits that RO can provide to both TC track and intensity forecasts. SIGNIFICANCE STATEMENT: The purpose of this study is to understand how utilizing larger numbers (relative to what is operationally available) of radio occultation (RO) satellite observations in a hurricane model can impact tropical cyclone forecasts. It is important to determine the value of these additional data for possible commercial RO data purchases as well as developing future RO satellite missions. Our results show improvements to both track and intensity forecasts for tropical cyclones after using these additional data in the model.