Assimilation of Surface-Based Boundary Layer Profiler Observations during a Cool-Season Weather Event Using an Observing System Simulation Experiment. Part I: Analysis Impact

• Published in: Monthly weather review Vol. 139; no. 8; pp. 2309 - 2326
• Main Authors: OTKIN, Jason A, HARTUNG, Daniel C, TURNER, David D, PETERSEN, Ralph A, FELTZ, Wayne F, JANZON, Erik
• Format: Journal Article
• Language: English
• Published: Boston, MA American Meteorological Society 01.08.2011
• Subjects: Accuracy; Atmospherics; Boundary layers; Climatology; Councils; Data collection; Earth, ocean, space; Exact sciences and technology; External geophysics; Lidar; Meteorology; Moisture; Moisture profiles; Profiling; Random access memory; Remote sensing; Sensors; Studies; Troposphere; Water vapor; Weather; Weather forecasting; Wind; United States; Extratropical zone; Temperature distribution; Wind field; Interferometer; Microwave radiometer; Ensemble Kalman filter; Surface layer; remote sensing; case studies; troposphere; North America; trajectory; Winter; water vapor; winds; Radar observation; Lidar; Doppler radar; Data assimilation; radiance
• ISSN: 0027-0644; 1520-0493
• DOI: 10.1175/2011MWR3622.1

Abstract In this study, an Observing System Simulation Experiment was used to examine how the assimilation of temperature, water vapor, and wind profiles from a potential array of ground-based remote sensing boundary layer profiling instruments impacts the accuracy of atmospheric analyses when using an ensemble Kalman filter data assimilation system. Remote sensing systems evaluated during this study include the Doppler wind lidar (DWL), Raman lidar (RAM), microwave radiometer (MWR), and the Atmospheric Emitted Radiance Interferometer (AERI). The case study tracked the evolution of several extratropical weather systems that occurred across the contiguous United States during 7–8 January 2008. Overall, the results demonstrate that using networks of high-quality temperature, wind, and moisture profile observations of the lower troposphere has the potential to improve the accuracy of wintertime atmospheric analyses over land. The impact of each profiling system was greatest in the lower and middle troposphere on the variables observed or retrieved by that instrument; however, some minor improvements also occurred in the unobserved variables and in the upper troposphere, particularly when RAM observations were assimilated. The best analysis overall was achieved when DWL wind profiles and temperature and moisture observations from the RAM, AERI, or MWR were assimilated simultaneously, which illustrates that both mass and momentum observations are necessary to improve the analysis accuracy.