How mapping the weather 12,000 years ago can help predict future climate change
The end of the last ice age, around 12,000 years ago, was characterised by a final cold phase called the Younger Dryas. Scandinavia was still mostly covered in ice, and across Europe the mountains had many more, and larger, glaciers than today. There was a substantial icefield in the west of Scotland and glaciers could be found on many mountains across the British Isles.
Not surprisingly, the climate was colder back then, especially in winter, with temperatures in the UK getting down to -30°C or lower. Despite these freezing ice-age winters, differences in the Earth’s orbit around the Sun meant the summers were relatively warm, with an average temperature in July between 7°C and 10°C across most of the UK and Ireland.
Then, as now, the polar front jet stream (a high-altitude fast-moving wind belt) had a major influence on the weather across Europe, bringing precipitation (rain and snow) from the Atlantic across the continent. However, before the time of written climate records, the timing, quantity and pattern of precipitation are poorly understood.
Our new study has used glaciers that existed during the Younger Dryas to determine the precipitation patterns and path of the jet stream across Europe at that time. We identified glacial landforms called moraines at 122 sites from Morocco in the south to Norway in the north, and from Ireland in the west to Turkey in the east, which demonstrated the presence of glaciers some 12,000 years ago.
We reconstructed the 3D geometry of each of these glaciers using knowledge of the way that ice flows across the landscape. From the reconstructed ice surfaces, we could determine an important point on each of these glaciers, the equilibrium line altitude which is linked to climate via yearly precipitation and average summer temperature.
It is essentially the altitude on the glacier where snow accumulation and snow melt are equal at the end of September and can be seen as the snowline. The results provided a map of precipitation across Europe about 12,000 years ago which was controlled by the jet stream.
Jet stream weather
What the results showed was that the UK, Ireland, Portugal and Spain were mostly wetter than the present day, as was the Mediterranean, especially in the east – the Balkans, Greece and Turkey. It was relatively drier across much of France, Belgium, the Netherlands, Germany and farther east across Europe. These areas of wetter and drier climate allowed us to identify the location of the jet stream.
We surmised that the jet stream passed over the wetter regions bringing with it the storms (known as mid-latitude depressions) we are all familiar with in the UK – especially Scotland – and also potentially generated other smaller, more intense storms. Based on the path of the jet stream it is believed that the autumn and spring were wettest in the UK and Ireland and that the winters were drier.
Across Portugal, Spain and the Mediterranean, the winter months were probably the wettest, with autumn and spring being somewhat drier. This is the first time that we have had an insight into the seasonal weather patterns across Europe during the Younger Dryas, and indeed such glimpses of past climate, beyond the period for which we have recorded climate observations, are rare.
Normally it is only numerical climate models that reveal such a regional scale view on past atmospheric circulation, storm tracks and precipitation. Numerical climate models plot our weather and climate by dividing the atmosphere, Earth’s surface and ocean into multiple interconnected cells, vertically and horizontally, in a three-dimensional grid, and solve complex mathematical equations to determine how energy and matter move through the system.
Changing jet stream
In our study, a comparison of the glacier-derived precipitation from 12,000 years ago was made with the outputs from several palaeoclimate (the study of climate in the past) computer simulations. Numerical climate models are extremely complex, yet they remain a simplification of reality, so different models inevitably generate outputs which variously agree and disagree.
The general pattern of precipitation determined from our study of the palaeo-glaciers agreed with some parts of the climate model outputs, but in disagreement with others – for example, none of the climate models identified all of the UK, Ireland, Portugal, Spain and Mediterranean as being wetter in the past.
We are already seeing signs that the jet stream may be changing as the climate warms and it is thought that it will probably move northwards and become wavier. These ripples could lead to more extremes, for example, heatwaves in summer and more storms and flooding in the winter.
To understand how climate will change in the future we rely on computer models, but these models do not yet agree on what happened in the past nor on exactly what will happen in the future. To make better future predictions from ongoing climate warming, palaeoclimate datasets, such as the glacier-derived precipitation determined from our study, can be used to test the computer models.
When the models can better reproduce precipitation patterns reconstructed from past climates, especially in periods when the jet stream has moved, then our confidence in their predictions of future climate will also be boosted.
This work was funded by the Leverhulome Trust International Network Grant IN-2012-140.
source: The Conversation: How mapping the weather 12,000 years ago can help predict future climate change