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- Title
An extremes-weighted empirical quantile mapping for global climate model data bias correction for improved emphasis on extremes.
- Authors
Rohith, A. N.; Cibin, Raj.
- Abstract
Accuracy in the global climate model (GCM) projections is essential for developing reliable impact mitigation strategies. The conventional bias correction methods used to improve this accuracy often fail to capture the extremes, specifically for precipitation, due to the generic correction application to whole data. Given the importance of understanding future extreme precipitation behavior for disaster mitigation, we propose Extremes-Weighted Empirical Quantile Mapping (EW-EQM) bias correction with a specific emphasis on extremes. The EW-EQM applies separate EQM correction to threshold-exceeded extremes and frequency-adjusted non-extreme precipitation occurrences. The bias correction results demonstrated using station-observed precipitation records at 945 locations in the Mid-Atlantic region of the United States, and five Coupled Model Intercomparison Project Phase 6 (CMIP6) GCMs demonstrate the strength of EW-EQM to improve the bias correction abilities of extreme precipitation occurrences. The spatial median of Root Mean Square error between observed and bias-corrected extreme precipitation was mostly less than 6 mm for EW-EQM across GCMs, while EQM and Power Transformation had a median higher than 12 mm. Further, future bias-corrected precipitation series for 2021–2050 under SSP245 indicate a 0–10% increase in total annual precipitation and a 10% decrease to 25% increase in mean annual maximum precipitation in the region. The improved bias correction of extremes could be significant in climate change impact mitigation decisions such as flood management. Highlights: An Extremes-Weighted Empirical Quantile Mapping (EW-EQM) climate data bias correction is proposed. The EW-EQM gives specific emphasis on the threshold exceedance extreme precipitation events. The EW-EQM outperforms conventional EQM for extreme precipitation events. An increase of up to 25% in mean extreme precipitation is for the Mid-Atlantic region of the US under SSP245 in the near future. EW-EQM preserves the raw GCM trends for extremes, while EQM does not.
- Subjects
MIDDLE Atlantic States; CLIMATE change models; STANDARD deviations; CLIMATE change mitigation; PRECIPITATION (Chemistry); HAZARD mitigation
- Publication
Theoretical & Applied Climatology, 2024, Vol 155, Issue 6, p5515
- ISSN
0177-798X
- Publication type
Article
- DOI
10.1007/s00704-024-04965-z