Ville VAKKARI

Nationality Finnish
Year of selection2015
InstitutionFinnish Meteorological Institute
CountryFinland
RiskEnvironmental risks

Type of support

Post-Doctoral Fellowship

Granted amount

120 000 €

Duration

2 years

Air quality forecasts, designed to warn you of hazardous pollution in the air, may be underestimating the risk when it comes to major fires. During a fire, a plethora of tiny particles and trace gases are released in the smoke. Tiny and trace though they may be, they add up, interact and change with time. Today’s models that predict air quality in the region near a fire tend to underestimate the number of particles, a discrepancy that researchers have to correct for. Dr. Ville Vakkari is taking an innovative approach to improving these local predictions and to understanding what it means for the global climate when these substances enter the atmosphere.
He is producing entirely new information by combining ground-based measurements of airborne particles in the smoke with satellite data capable of identifying the very fire they came from. The latter will allow him to correlate particle characteristics with the age of the fire, the type of environment it was consuming, whether it was burning with flame or quietly smoldering… All of these are clues to the type and number of particles that found their way into the air and what happened to them next.
The protagonists in this story are the aerosol particles generated by a fire. As small as a nanometer (one billionth of a meter), there are thousands of them suspended in every cubic centimeter of air. Other players are in gas form and interactions among them or with sunlight can trigger chemical reactions, potentially growing the tiny particles to climatically relevant sizes or producing a secondary set of particles. Identifying the particles present, and the balance among them, is important for Dr. Vakkari, because of their sometimes opposite effects on the climate. Soot, for example, absorbs solar radiation, leading to heating; others, including secondary particles, reflect it, causing cooling, instead. More particles in the atmosphere will also make clouds last longer and make them brighter—two factors that can lead to cooling. “For both cases, the question is how particle properties change during smoke plume transport,” he explains. Dr. Vakkari adds that “burning crop residues is a common agricultural practice around the world, but this is not necessarily a good thing.” Add that to the increased risk of natural fires due to extreme droughts linked to climate change, and we all have an interest in understanding what these tiny particles, born of fire, get up to in our air.

Scientific title : Atmospheric Evolution Of Biomass Burning Emissions

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