The first global analysis of the whole of 2016 has confirmed last year as the warmest on record and saw the planet near a 1.5°Cwarming, according to the Copernicus Climate Change Service (C3S).
The latest figures from C3S, part of the EU's
Copernicus earth observation programme, LINK show that 2016's global temperature
exceeded 14.8°C, and was around 1.3°C higher than typical for the middle years
of the 18th century. 2016 was close to 0.2°C warmer than 2015, which was
previously the warmest year on record.
Countries agreed in Paris in 2015 to holding the
increase in the global average temperature to well below 2 °C above pre-industrial levels and to pursue efforts
to limit the temperature increase to 1.5 °C
above pre-industrial levels, recognizing that this would significantly reduce
the risks and impacts of climate change.
A more
dangerous climate
Global warming increases the likelihood of extreme
weather events such as heatwaves, droughts and floods. Future warming could
cause billions of euro of damage each year and affect the availability of fresh
water and crop yields in the most vulnerable countries.
Director of ECMWF's Copernicus Services Juan Garcés de
Marcilla said:
We are already seeing around the globe the impacts of a changing climate. Land and sea temperatures are rising along with sea-levels, while the world's sea-ice extent, glacier volume and snow cover are decreasing; rainfall patterns are changing and climate-related extremes such as heatwaves, floods and droughts are increasing in frequency and intensity for many regions. The future impact of climate change will depend on the effort we make now, in part achieved by better sharing of climate knowledge and information.To help decision-makers develop effective adaptation and mitigation solutions we make the data from Copernicus Climate Change Service (C3S) and the Copernicus Atmosphere Monitoring Service (CAMS) freely and openly available. By mainstreaming the information that the Copernicus Services hold into climate policy and strategy, governments, the private sector and society can identify and unite around opportunities to tackle further climate change and reduce vulnerability where its effects are unavoidable.
C3S found that global
temperatures in February 2016 already touched the 1.5°C limit, though under the influence of a strong El
Niño, an intermittent event involving a period of warming. Global temperatures
still remained well above average in the second half of 2016, associated partly
with exceptionally low sea-ice cover in both the Arctic and Antarctic.
C3S found that most regions around the world
experienced above-average temperatures during 2016. The largest differences in
regional average temperatures were found in the Arctic but conditions were also
extreme over southern Africa early in the year, over southern and south-eastern
Asia prior to the summer monsoon, over the Middle East later in summer, and
over parts of North America in summer and autumn.
In addition to record temperatures, ECMWF's Copernicus
Services monitored other extremes occurring in 2016, including significant
global wildfires and the growth of CO2 in the atmosphere.
Destructive fires were observed around Fort McMurray, Canada in May and then
extensive wildfires across Siberia, associated with the year's high surface
temperatures, during June and July.
For the first year CO2 levels did not
return below 400 ppm as summer turned to autumn in the Northern Hemisphere. In
previous years, take-up of CO2 by vegetation during the summer
growing season has typically seen September mark the lowest point for CO2levels.
Note on data
Copernicus temperature data are based on millions of diverse daily measurements analysed by the European Centre for Medium-Range Weather Forecasts (ECMWF) using methods developed for weather forecasting.
Annual global temperature variations derived from Copernicus data and from other widely used sets of data typically agree to better than 0.1°C for recent years. The spread in values is likely to be larger than 0.1°C for 2016 due to differences in the extent to which datasets represent the warm conditions associated with exceptionally low sea-ice cover.
The estimate used here is that the climatological average temperature around the start of the Industrial Revolution is estimated to have been 0.7°C lower than that for 1981-2010.