stefano.serafin(at)univie.ac.at
Josef-Holaubek-Platz 2 (UZA II), 1090 Vienna
Roomnumber: 2G556
T: +43-1-4277-537 13
- 2020: Senior Scientist, University of Vienna
- 2018: National scientific qualification (Italy), disciplines 04/A4 (Geophysics) and 02/C1 (Astronomy, Astrophysics, Earth and Planetary Sciences)
- 2018: Project leader, University of Innsbruck
- 2010: Assistant professor, University of Vienna
- 2006: Doctorate in Environmental Engineering, University of Trento (Italy)
- 2002: Project scientist, CETEMPS/University of L'Aquila (Italy)
- 2002: Degree in Environmental Science, University of Milano-Bicocca (Italy)
- Complete curriculum vitae
Research Interests
- Mountain meteorology
- Dynamic meteorology
- Numerical weather prediction
- Boundary-layer meteorology
Projects
- 2024-2028: FWF (Austrian Science Fund) Stand-alone project P 37259, "DEmonstrating Parameter Estimation with eNsemble-based Data Assimilation for Boundary-Layer modElling over mountains"
- 2018-present: TEAMx (Multi-scale transport and exchange processes in the atmosphere over mountains – Programme and experiment)
- 2018-2022: FWF (Austrian Science Fund) Stand-alone project P 30808, "Multiscale Interactions in Convection Initiation in the Alps"
- 2012-2015: FWF (Austrian Science Fund) Stand-alone project P 24726, "STABLEST: Stable boundary layer separation and turbulence"
Links
- ORCID / ResearcherID / Scopus profiles
- Department of Atmospheric and Cryospheric Sciences (ACINN), University of Innsbruck
- Department of Civil, Environmental and Mechanical Engineering, University of Trento
- CETEMPS, University of L'Aquila
Publications
Can ensemble‐based parameter estimation aid parameterization design?
- Author(s)
- Stefano Serafin, Martin Weissmann
- Abstract
Ensemble-based data assimilation algorithms can be exploited to estimate uncertain parameters in parameterization schemes by means of state augmentation. Parameters are appended to the model state vector and, just like state variables, they are optimized objectively on the basis of flow-dependent ensemble covariances with observable quantities. Ensemble-based parameter estimation (PE) is a well-established methodology and has been used recently to account for model errors in the assimilation process. In this study, we discuss if and how it can be a useful tool for parameterization design. With simple experiments tailored to turbulence modelling, we demonstrate that quickly converged and physically interpretable empirical parameters can be obtained only under restrictive conditions. The error variance of the assimilated observations needs to be as low as that of the state perturbations induced by the parameter to be estimated, and parametric uncertainty must be the dominant contributor to the uncertainty of the assimilation ensemble. Based on these results, we outline a possible strategy for offline PE targeted at parameterization development. The strategy relies on ensemble-based PE experiments that ingest synthetic observations from high-resolution nature runs, in which the parameterized process is fully resolved; it is thus potentially well suited to refine the design of, for example, boundary-layer turbulence, convection, or orographic drag parameterizations. We also demonstrate that optimally converged parameters can, to some extent, compensate for structural errors in parameterizations, and suggest exploiting this property to extend the flexibility of parameterization schemes. This can be achieved by replacing fixed parameters with adaptive parameters, drawn from lookup tables compiled from parameter estimation results.
- Organisation(s)
- Department of Meteorology and Geophysics
- Journal
- Quarterly Journal of the Royal Meteorological Society
- ISSN
- 0035-9009
- DOI
- https://doi.org/10.1002/qj.5031
- Publication date
- 06-2025
- Peer reviewed
- Yes
- Austrian Fields of Science 2012
- 105206 Meteorology
- Keywords
- ASJC Scopus subject areas
- Atmospheric Science
- Portal url
- https://ucrisportal.univie.ac.at/en/publications/4792f6c0-4417-42e8-b395-e3693ec2daa3