Fallow agricultural land and steppe-formation processes are evidently capable of having a much greater effect on global air quality than was previously assumed.
This is the conclusion drawn by researchers after examining a dust cloud that formed over parched fields in southern Ukraine and led to extremely high concentrations of particulate matter in Central Europe. On 24 March 2007 the dust cloud spread across Slovakia, Poland and the Czech Republic to Germany.
Peak concentrations of between 200 and 1400 micrograms of PM10 particulates per cubic metre were measured. By way of comparison: the EU daily average limit is 50 micrograms per cubic metre. Even if such meteorological conditions would appear to occur relatively infrequently, the unexpected scale of the phenomenon showed a need for a better understanding of the processes that lead to the formation and transport of such large quantities of dust. Writing in the journal Atmospheric Chemistry and Physics, the researchers from the Leibniz Institute for Tropospheric Research (IfT), Freie Universität Berlin, the Helmholtz Centre for Environmental Research (UFZ) and Saxony’s regional office of the environment and geology (LfUG) explain that this is particularly relevant in the context of human-induced desertification and climate change. Previously, the Sahara had been seen as the main source of dust carried over long distances to Central Europe. The paper published by the research team from Leipzig, Berlin and Dresden is the first documentation of dust transport from the Ukraine.
Blown by the wind
It was a warm, sunny day in spring and a strong wind was blowing over the parched fields near the Kachowkaer dam on the lower reaches of the Dnjepr river. There had been no rain for weeks. The black soil here in the south of the Ukraine is one of the most fertile soils in the world, but it is also very fine and therefore particularly sensitive to erosion. On this day, 23 March 2007, gusts of wind with speeds of up to 90 kilometres per hour were whipping up huge quantities of dust in the steppe. A dust cloud formed that was so big that it was later clearly visible on the weather satellite infrared pictures. At this point, no one living 1500 kilometres to the west suspected what was in store for people in Germany and their eastern neighbours.
Thanks to an area of high pressure over Scandinavia and an area of low pressure moving from the Black Sea to Italy, the air mass quickly drifted to Central Europe. Just one day later the air with its cargo of fine dust from the Ukrainian fields had arrived in Germany.
Tracking down a mystery
In Germany, people in the Erz Mountains were not a little surprised when the sky took on a slightly yellow sheen. The controllers from the state air monitoring network also realised very quickly that something unusual had happened.
Their filters were a much browner colour than usual, which meant that there must have been a lot more dust in the air.
In the offices of the particulate experts at the Leibniz Institute for Tropospheric Research the phones were ringing. Dr Wolfram Birmili has for years been investigating the long-distance transport of particulates in the troposphere, i.e. the lower few kilometres of the atmosphere. He and his colleagues quickly ruled out the classic air pollutants, such as coal-fired power stations and forest fires, because their measuring instruments showed unusually high levels of coarse-grained particles (larger than 0.001 mm) in the dust plume. The relatively low carbon monoxide and carbon dioxide concentrations also seemed to rule out industrial sources and biomass combustion. Dust from the Sahara Desert had caused a stir in Germany several times in the past. But the Sahara was not a possibility either, because the weather conditions were wrong – the wind was coming from the east. So where was the dust coming from? The detective work began.
Satellite pictures solve the riddle
The directive on particulate matter has been in force in the European Union since 2005. As a consequence, there is a comprehensive air monitoring network in the member states designed to monitor compliance with the limit values. With quick, unbureaucratic assistance from a total of 15 state environmental agencies it was possible to analyse particulate data from 360 stations in five countries. It quickly became apparent that the particulate matter was coming from the east because the concentration increased noticeably towards Slovakia.But where exactly had the cloud come from? What the situation was like the other side of the EU’s eastern border was a matter for speculation because of a lack of air monitoring data. So the researchers combed satellite pictures and came across what they were looking for on a EUMETSAT picture. This showed a noticeable red patch over southern Ukraine on 23 March which expanded rapidly. The researchers estimated the total mass of the dust cloud to be at least 60,000 tons. That is equivalent to more than 600 wagonloads of sand. The actual mass was probably much greater still, since the measuring devices register only those particles that are smaller than 10 microns (0.01 mm). Czech geologists estimated the total dust load must be about 3 million tons because this Ukrainian "plume" contained also bigger particles till size of 0.5mm. The last remaining doubts about the origin of the dust cloud were cleared up by a team led by Dr Jindrich Hladil at the Institute of Geology of the Czech Academy of Sciences in Prague. They compared the dust samples from the air with dust samples taken directly from the Ukrainian soil. The lead isotope ratio showed that the dust had indeed come from the Black Sea region. "The mineralogical-petrological fingerprinting of the solid particles over 10 micrometre size can say a lot about the geologically specific source areas", says Jindrich Hladil.
explains Wolfram Birmili.
A foretaste of the consequences of climate change Over two-thirds of the land area in the Ukraine consists of fields and meadows. The soil on 220,000 square kilometres is regarded as being under threat. Since the 1930s wind erosion in what was then the Soviet Union has increased considerably as a result of collectivisation in agriculture and the resultant large field areas. In particular, this has affected the regions north of the Caucasus, the lower reaches of the Don river and eastern and southern Ukraine.
It is possible that the process is also accelerated by climate change. In particular, previously unaffected semi-arid regions are continuing to dry out. A normal dust storm can result in 70 tons of the light black soil being whirled up per hectare per hour. "According to Russian studies, in the past 40 years there have been three to five such dust storms per year on average in the Ukrainian steppe," Birmili reports. "Our institute has been constantly monitoring the airborne particles and their components at the Melpitz research station near Leipzig for around 15 years. We analysed all these measurements again retrospectively but were unable to detect any comparable dust cloud from the Black Sea area. This makes the dust cloud of 24 March 2007 unusual. But who can say that such weather conditions may not occur more frequently in future as a result of climate change?"
Small particles with a big effectThe research findings put a new complexion on the attempts being made by many local authorities to comply with the particulate limits using a wide range of measures. In the greater Berlin area for instance, scientists estimate that half of the particulate volumes come from regional and remote sources, rather than from local sources. Besides salt particles, soil particles form the largest mass of particles in the atmosphere. Scientists estimate that there are between 1,000 and 2,000 million tons of dust circulating around the world in the lower layers of the atmosphere in annual totals. This would be equivalent to the cargo of a goods train long enough to encircle the globe five times. This particulate matter comes primarily from arid areas and deserts, i.e. from the Sahara, the Arabian peninsula, the Gobi Desert and the Taklimakan Desert in Asia, and the deserts in Australia and South America. One-fifth is believed to be caused by human activity, such as field cultivation. And there are consequences for the climate because dust particles in the air block solar radiation trying to enter the atmosphere and block heat radiation escaping into space and are therefore the largest unknown factor in climate models.
Moreover, not much is known about the possible health impacts of such long-distance transport of dust aerosols.more information:
links:Leibniz Institute for Tropospheric Research (IfT):
Academy of Sciences CR, Institute of Botany, Department of Ecology, Palynology & Paleoecology Branch http://ekolbrno.ibot.cas.cz/
Charles University, Faculty of Science, Institute of Geochemistry, Mineralogy and Mineral Resources & Laboratories of the Geological Institutes, ICP Laboratory http://www.natur.cuni.cz/ugmnz/icplab/
Czech Geological Survey, Environmental geochemistry & biogeochemistry http://www.geology.cz/extranet-engEuropean Loess Map:
http://www.iamo.de/Soil research at Helmholtz Centre for Environmental Research (UFZ):
Tilo Arnhold | UFZ Leipzig-Halle
Plasma-zapping process could yield trans fat-free soybean oil product
02.12.2016 | Purdue University
New findings about the deformed wing virus, a major factor in honey bee colony mortality
11.11.2016 | Veterinärmedizinische Universität Wien
In recent years, lasers with ultrashort pulses (USP) down to the femtosecond range have become established on an industrial scale. They could advance some applications with the much-lauded “cold ablation” – if that meant they would then achieve more throughput. A new generation of process engineering that will address this issue in particular will be discussed at the “4th UKP Workshop – Ultrafast Laser Technology” in April 2017.
Even back in the 1990s, scientists were comparing materials processing with nanosecond, picosecond and femtosesecond pulses. The result was surprising:...
Have you ever wondered how you see the world? Vision is about photons of light, which are packets of energy, interacting with the atoms or molecules in what...
A multi-institutional research collaboration has created a novel approach for fabricating three-dimensional micro-optics through the shape-defined formation of porous silicon (PSi), with broad impacts in integrated optoelectronics, imaging, and photovoltaics.
Working with colleagues at Stanford and The Dow Chemical Company, researchers at the University of Illinois at Urbana-Champaign fabricated 3-D birefringent...
In experiments with magnetic atoms conducted at extremely low temperatures, scientists have demonstrated a unique phase of matter: The atoms form a new type of quantum liquid or quantum droplet state. These so called quantum droplets may preserve their form in absence of external confinement because of quantum effects. The joint team of experimental physicists from Innsbruck and theoretical physicists from Hannover report on their findings in the journal Physical Review X.
“Our Quantum droplets are in the gas phase but they still drop like a rock,” explains experimental physicist Francesca Ferlaino when talking about the...
The Max Planck Institute for Physics (MPP) is opening up a new research field. A workshop from November 21 - 22, 2016 will mark the start of activities for an innovative axion experiment. Axions are still only purely hypothetical particles. Their detection could solve two fundamental problems in particle physics: What dark matter consists of and why it has not yet been possible to directly observe a CP violation for the strong interaction.
The “MADMAX” project is the MPP’s commitment to axion research. Axions are so far only a theoretical prediction and are difficult to detect: on the one hand,...
16.11.2016 | Event News
01.11.2016 | Event News
14.10.2016 | Event News
07.12.2016 | Health and Medicine
07.12.2016 | Life Sciences
07.12.2016 | Health and Medicine