Assessing the performance of thermospheric modelling with data assimilation throughout solar cycles 23 and 24

Data assimilation procedures have been developed for thermospheric models using satellite density measurements as part of the EU Framework Package 7 ATMOP Project. Two models were studied; one a general circulation model, TIEGCM, and the other a semi-empirical drag temperature model, DTM. Results of...

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Bibliographic Details
Published in:arXiv.org 2015-03
Main Authors: Murray, Sophie A, Henley, Edmund M, Jackson, David R, Bruinsma, Sean L
Format: Article
Language:English
Subjects:
Data assimilation
Density
General circulation models
GRACE (experiment)
Satellites
Solar cycle
Solar maximum
Weather forecasting
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Summary:Data assimilation procedures have been developed for thermospheric models using satellite density measurements as part of the EU Framework Package 7 ATMOP Project. Two models were studied; one a general circulation model, TIEGCM, and the other a semi-empirical drag temperature model, DTM. Results of runs using data assimilation with these models were compared with independent density observations from CHAMP and GRACE satellites throughout solar cycles 23 and 24. Time periods of 60 days were examined at solar minimum and maximum, including the 2003 Hallowe'en storms. The differences between the physical and the semi-empirical models have been characterised. Results indicate that both models tend to show similar behaviour; underestimating densities at solar maximum, and overestimating them at solar minimum. DTM performed better at solar minimum, with both models less accurate at solar maximum. A mean improvement of ~4% was found using data assimilation with TIEGCM. With further improvements, the use of general circulation models in operational space weather forecasting (in addition to empirical methods currently used) is plausible. Future work will allow near-real-time assimilation of thermospheric data for improved forecasting.
ISSN:2331-8422
DOI:10.48550/arxiv.1503.03207