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Oslo city centre in Mid-December: Temperatures above freezing and no snow in sight. Photo by Iselin Rønningsbakk / CICERO.

Oslo city centre in Mid-December: Temperatures above freezing and no snow in sight. Photo by Iselin Rønningsbakk / CICERO.

The current winter is a big win for seasonal forecasts

News - News from CICERO

Published 03.02.2020

Seasonal forecasts for this winter were markedly accurate, with mild conditions in Northern Europe in December and January predicted already in October. Researchers in the S2S4E project are now working to find out how to improve the reliability of future outlooks.

As we wrote in October – before the onset of the current unusually mild winter in Northern Europe – the seasonal forecast models for this winter from the world’s six leading weather agencies all showed a clear signal for a positive North Atlantic Oscillation (NAO) phase.

“This normally translates into warmer and wetter weather than average in Northern Europe, and colder and drier conditions than normal in Southern Europe,” explains Nathalie Schaller, senior researcher at CICERO Center for International Climate Research, and involved in the S2S4E project.

The seasonal forecasts published in November for the December-February period, and in December for January-March were on the same path, and showed a clear positive NAO signal, with warmer than average temperatures in the northern part of Europe.

Temperatures in Europe in December and January were well above normal for the winter season. Temperature anomalies for December in the image on the left, and for January on the right.

Unusually mild December and January

Now that December and January are over, we see that the seasonal forecasts were right: this winter has so far been markedly warmer than normal in Europe, and temperature records have been broken in several countries, particularly in the northern part of the continent.

“The record high temperatures in December and January are likely due to a combination of the strong positive NAO phase, and the fact that the earth has already warmed by more than 1⁰C since pre-industrial times,” Schaller explains.

Over the coming months, researchers involved in the S2S4E project will analyse why the weather models turned out to be so accurate in their predictions for this winter, because understanding the reasons why could help scientists improve the models.

Lower than normal electricity demand

The unusually warm temperatures seen in December and January may have resulted in substantial reductions in electricity demand in Europe, due to a reduced need for heating.

So, in terms of energy trading, one thing is certain, and that is that this winter, the winners are those who have based their decisions on the seasonal forecasts.

“Modelling work within the S2S4E project has shown that each European country has a very different sensitivity to winter temperatures depending on multiple factors, such as the amount of electric heating installed, or the resilience of the population to cold weather,” explains Hannah Bloomfield, a researcher at the University of Reading, who is also involved in S2S4E project.

“The electricity demand in France is particularly sensitive to temperature, due to their reliance on electric heating. Here, temperatures in December and January averaged 3°C above the seasonal norm, and our models show power demand averaging 6 GW below normal,” Bloomfield says.

“In Sweden, meanwhile, it was about 5°C warmer than normal, and this implies that demand would have been around 2 GW lower than average,” says Bloomfield, adding that “similar results are seen in Norway and Finland.”

The latest forecasts from the world's six leading weather agencies suggest that the NAO+ may remain the dominant circulation pattern in February, March and April, resulting in continued mild weather in large parts of Europe. From left to right: The European Centre for Medium-Range Weather Forecasts (ECMWF), The Euro-Mediterranean Center on Climate Change (CMCC), The German Weather Service (DWD), Météo-France, the UK's Met Office and the US National Weather Service's NCEP.

More wintry conditions ahead?

But the winter is not over yet so the question remains: Could we still get some more winter weather before spring sets it?

If you look at the seasonal forecast model simulations launched at the beginning of January, the answer is no, as these indicate that the weather will remain warmer than normal until the end of April, explains Schaller.

“The latest medium-range weather forecast simulations show a similar picture, predicting an almost record positive NAO over the coming weeks, meaning Europe will see more of the same mild weather,” Schaller adds.

About S2S4E

S2S4E (Sub-Seasonal to Seasonal Climate Forecasting for Energy) is a project funded by the EU's research and innovation programme Horizon 2020, which is working to make long-term forecasts more reliable and useful.

To achieve this goal, S2S4E has developed a new forecasting tool particularly tailored for the energy industry – the S2S4E Decision Support Tool – which is free to use at least until the end of November 2020.

S2S4E is coordinated by Barcelona Supercomputing Center and the 12 partners in the project come from seven different countries in Europe (Spain, France, Norway, Germany, Italy, United Kingdom and Sweden).

For more information about the S2S4E project, please visit the project website.

The different weather regimes are large-scale recurrent atmospheric patterns which can be associated with different types of surface weather conditions. Temperature anomalies such as those from December and January are very similar to those seen in the positive phase of the North Atlantic Oscillation (NAO+), which you can see here in the blue box. Row 1 shows normalised electricity demand, row 2 shows mean sea level pressure (MSLP) anomalies, and row 3 shows temperature anomalies measured at a height of two metres during each of the regimes. The other weather regimes shown in this figure are the Negative phase of the North Atlantic Oscillation (NAO-), Scandinavian blocking (ScBL) and Atlantic Ridge (AR). Adapted from Bloomfield et al., 2019.