Scientists see closer to the Earth's atmospheric controlling the fine particle particles after identifying new connections between natural pollutants and human pollutants.
Fine particles are an air pollutant that can cause negative effects on human health when the air is too high and when it can affect the climate.
The breakthrough would lead to stronger and more detailed climate legislation and cleaner air from researchers. The University of Manchester and the German Forschungszentrum Jühlenhhung International are investigating the impact of the Aerosol Organic Aerosol (SOA) team.
SOA particles are very small and are made in the atmosphere of natural and human emissions. The trees, plants, cars or industrial emissions are created through complex interactions between solar and organic volatile compounds.
Small particles cause human physical and psychic health, and they are premature deaths of around 5.5 million people around the world. The effect of the climate particle is the greatest uncertainty regarding the effect of radiation effect on climate change.
International groups have studied the formation of SOA small particles between natural plants and the mixtures of humans and natural compounds that react to the laboratory. In any case, when a smaller particle was made, it was only reacted when reacted with the same amount of steam.
Earth Director, Professor Gordon McFiggans, at Manchester Earth's School and Environmental Sciences, explained that "we have long recognized that we have to take full account of the total blend of steam envisaged for the amount of secondary pollutants, such as ozone.
"Our discoveries now tell us what natural remedies we need to know and how to quantify the contamination of particles contaminated by natural compounds."
In the study, this type of first study is to analyze the influence of these complex masses of mass concentration in the atmospheric particle.
Professor Thomas Mentel, the author of the FZJ, added: "When we designed the experiment, we understood that the interaction between the two particles was diminished in a confusing manner. Composite traces react not only to reactive competition but to react to preventing the formation of particles.
"Including the effect of an experimentally looking global air quality model, we can significantly damage the mass of particles significantly in real atmospheric conditions, not just in the laboratory."
This quantification of the interaction between steam generating particles is shown for the first time in how complex pollutants are found in real-life atmospheric pollutants.
Professor McFiggans said: "Our work contributes to the future contribution of particles to understanding the air quality and climate contribution, including these results, and in addition to experimenting with numerical models, we can offer the right advice from politicians."