Subseasonal Weather Predictions in Northern Hemisphere Winter

Subseasonal-to-Seasonal (S2S), or extended-range, weather predictions cover lead times of up to two months, bridging the gap between medium-range and seasonal forecasts. Accurate predictions at this time-range are important in many socio-economic sectors, including agriculture, energy, and transport...

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Bibliographic Details
Main Author: Erner, Irene
Other Authors: Finnish Meteorological Institute, University of Helsinki, Faculty of Science, Helsingin yliopisto, matemaattis-luonnontieteellinen tiedekunta, Helsingfors universitet, matematisk-naturvetenskapliga fakulteten, Messori, Gabriele, Karpechko, Alexey, Järvinen, Heikki, orcid:0000-0003-3066-1902
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: Finnish Meteorological Institute 2025
Subjects:
Subseasonal predictions
Stratosphere-troposphere coupling
Polar vortex
Cold spells
Predictability
forecasts
weather forecasting
stratosphere
climate changes
arctic region
troposphere
ennusteet
säänennustus
ennustettavuus
stratosfääri
ilmastonmuutokset
antarktinen alue
troposfääri
ilmakehä
114 Fysiikka
1172 Ympäristötiede
114 Fysik
1172 Miljövetenskap
114 Physical sciences
1172 Environmental sciences
Arctic
Online Access:http://hdl.handle.net/10138/591740
https://doi.org/10.35614/isbn.9789523362031
Description
Summary:Subseasonal-to-Seasonal (S2S), or extended-range, weather predictions cover lead times of up to two months, bridging the gap between medium-range and seasonal forecasts. Accurate predictions at this time-range are important in many socio-economic sectors, including agriculture, energy, and transport. The progress in S2S forecasting has been moderate due to the complexities of atmospheric processes and limitations in numerical models. Unlike medium-range weather forecasting, which predicts weather conditions up to 15 days ahead, S2S predictions do not leverage predictability from initial conditions. Nor do they fully exploit the predictability from boundary conditions, which play a significant role in seasonal outlooks. However, forecast quality can be improved under specific atmospheric conditions. The overall objective of this study is to identify new sources of predictability at the S2S timescale which can increase forecast accuracy. This thesis contributes to subseasonal predictability research, analysing potential windows of opportunity for more accurate forecasting and enhancing existing knowledge in the field. The thesis mainly focuses on the variability of the stratospheric polar vortex and stratosphere-troposphere coupling as a source of additional predictability during the Northern Hemisphere winter. The most prominent phenomenon of the stratospheric variability is Sudden Stratospheric Warming (SSW), which often has a significant impact on tropospheric weather. Paper I of the thesis presents a case study of the 2018 SSW event, which led to a severe cold spell over Northern Eurasia. The study investigates the processes responsible for triggering the stratospheric warming and evaluates the predictability of the event. It was found that accurately capturing the chain of events, which began with anticyclonic Rossby wave breaking, followed by blocking and a record high eddy heat flux, was crucial for the early prediction of the SSW. Furthermore, precisely reproducing both the timing and intensity of the ...

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