(a) Annual mean temperature anomalies in the Arctic (66.5∘–90∘N) (dark colours) and globally (light colours) during 1950–2021 derived from the various observational datasets. Temperature anomalies have been calculated relative to the standard 30-year period of 1981–2010. Shown are also the linear temperature trends for 1979–2021. (b) Annual mean temperature trends for the period 1979–2021, derived from the average of the observational datasets. Areas without a statistically significant change are masked out. (c) Local amplification ratio calculated for the period 1979–2021, derived from the average of the observational datasets. The dashed line in (b) and (c) depicts the Arctic Circle (66.5∘N latitude). Graphic: Rantanen, *et al*., 2022 / *Communications Earth and Environment*

PARIS, 11 August 2022 (AFP) – The Arctic has warmed nearly four times faster than the rest of the planet over the last 40 years, according to research published Thursday that suggests climate models are underestimating the rate of polar heating.

The United Nations’ climate science panel said in a special report in 2019 that the Arctic was warming “by more than double the global average” due to a process known as Arctic amplification.

This occurs when sea ice and snow, which naturally reflect the Sun’s heat, melt into sea water, which absorbs it instead.

While there is a long-held consensus among scientists that the Arctic is warming quickly, estimates vary according to the timeframe studied and the definition of what constitutes the geographic area of the Arctic.

A team of researchers based in Norway and Finland analysed four sets of temperature data gathered by satellite studies since 1979 — the year when satellite data became available — over the entire Arctic circle.

They found that on average the data showed the Arctic had warmed 0.75C per decade, nearly four times quicker than the rest of the planet.

“The take in the literature is that the Arctic is warming about twice as fast as the globe, so for me it was a bit surprising that ours was so much higher than the usual number,” Antti Lipponen, co-author from the Finnish Meteorological Institute, told AFP.

The study, published in the journal Communications Earth & Environment, found significant regional variations in warming rate within the Arctic circle.

Climate change is caused by humans. As the Arctic warms up its glaciers will melt, and this will globally affect sea levels.
Antti Lipponen, PhD, Senior Scientist at the Finnish Meteorological Institute

For example, the Eurasian sector of the Arctic Ocean, near the Svalbard and Novaya Zemlya archipelagos, has warmed as much as 1.25C per decade — seven times faster than the rest of the world.

The team found that even state-of-the-art climate models predicted Arctic warming to be approximately one third lower than what the observed data showed.

They said that this discrepancy may be due to previous modelled estimates being rendered out of date by continued Arctic modelling.

“Maybe the next step would be to take a look at the models and I would be really interested in seeing why the models do not reproduce what we see in observations and what impact that is having on future climate projections,” said Lipponen.

As well as profoundly impacting local communities and wildlife that rely on sea ice to hunt, intense warming in the Arctic will have worldwide repercussions.

The Greenland ice sheet, which recent studies warn may be approaching a melting “tipping point”, contains enough frozen water to lift Earth’s oceans some six metres.

“Climate change is caused by humans. As the Arctic warms up its glaciers will melt and this will globally affect sea levels,” said Lipponen.

“Something is happening in the Arctic and it will affect us all.”

Arctic warming four times faster than rest of Earth: study

The 43-year Arctic amplification (AA) ratio derived from (a) CMIP5, (b) CMIP6, (c) MPI-GE and (d) CanESM5 realizations (thin grey lines) for all 43-year periods ending in 2000–2040. The x-axis represents the ending year of the 43-year AA ratios. Thick black lines represents the ensemble mean AA, calculated as a mean of ratios, not ratio of means. Observations (red lines) extend to 2021. 43-year AA ratios starting after 1970 and ending by 2040 are considered in the probability calculations (Section “Likelihood of observed Arctic amplification 1979–2021 in climate model simulations”) and shown with light background. The Arctic is defined as the area north of 66.5∘N. Graphic: Rantanen, et al., 2022 / Communications Earth and Environment — The 43-year Arctic amplification (AA) ratio derived from (a) CMIP5, (b) CMIP6, (c) MPI-GE and (d) CanESM5 realizations (thin grey lines) for all 43-year periods ending in 2000–2040. The x-axis represents the ending year of the 43-year AA ratios. Thick black lines represents the ensemble mean AA, calculated as a mean of ratios, not ratio of means. Observations (red lines) extend to 2021. 43-year AA ratios starting after 1970 and ending by 2040 are considered in the probability calculations (Section “Likelihood of observed Arctic amplification 1979–2021 in climate model simulations”) and shown with light background. The Arctic is defined as the area north of 66.5∘N. Graphic: Rantanen, *et al*., 2022 / *Communications Earth and Environment*

The Arctic has warmed nearly four times faster than the globe since 1979

ABSTRACT: In recent decades, the warming in the Arctic has been much faster than in the rest of the world, a phenomenon known as Arctic amplification. Numerous studies report that the Arctic is warming either twice, more than twice, or even three times as fast as the globe on average. Here we show, by using several observational datasets which cover the Arctic region, that during the last 43 years the Arctic has been warming nearly four times faster than the globe, which is a higher ratio than generally reported in literature. We compared the observed Arctic amplification ratio with the ratio simulated by state-of-the-art climate models and found that the observed four-fold warming ratio over 1979–2021 is an extremely rare occasion in the climate model simulations. The observed and simulated amplification ratios are more consistent with each other if calculated over a longer period; however the comparison is obscured by observational uncertainties before 1979. Our results indicate that the recent four-fold Arctic warming ratio is either an extremely unlikely event, or the climate models systematically tend to underestimate the amplification.