Sensitivity of Diesel Particulate Material Emissions and Composition to Blends of Petroleum Diesel and Biodiesel Fuel |
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| Authors: | Kento T. Magara-Gomez Michael R. Olson Tomoaki Okuda Kenneth A. Walz James J. Schauer |
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| Affiliation: | 1. Department of Civil and Environmental Engineering, Environmental Chemistry and Technology Program , University of Wisconsin-Madison , Madison , Wisconsin , USA;2. Department of Environmental Engineering , Pontificia Bolivariana University-Bucaramanga , Bucaramanga , Colombia;3. Department of Civil and Environmental Engineering, Environmental Chemistry and Technology Program , University of Wisconsin-Madison , Madison , Wisconsin , USA;4. Department of Applied Chemistry, Faculty of Science and Technology , Keio University , Kohoku-ku , Yokohama , Japan;5. Department of Chemistry, Madison Area Technical College , Madison , Wisconsin , USA |
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| Abstract: | A number of investigations have examined the impact of the use of biodiesel on the emissions of carbon dioxide and regulated emissions, but limited information exists on the chemical composition of particulate matter from diesel engines burning biodiesel blends. This study examines the composition of diesel particulate matter (DPM) emissions from a commercial agriculture tractor burning a range of biodiesel blends operating under a load that is controlled by a power take off (PTO) dynamometer. Ultra-low sulfur diesel (ULSD) fuel was blended with soybean and beef tallow based biodiesel to examine fuels containing 0% (B0), 25% (B25), 50% (B50), 75% (B75), and 100% (B100) biodiesel. Samples were then collected using a dilution source sampler to simulate atmospheric dilution. Diluted and aged exhaust was analyzed for particle mass and size distribution, PM2.5 particle mass, PM2.5 organic and elemental carbon, and speciated organic compounds. PM2.5 mass emissions rates for the B25, B50, and B75 soybean oil biodiesel mixtures had 20%–30% lower emissions than the petroleum diesel, but B100 emissions were about 40% higher than the petroleum diesel. The trends in mass emission rates with the increasing biodiesel content can be explained by a significant decrease in elemental carbon (EC) emissions across all blending ranges and increasing organic carbon (OC) emissions with pure biodiesel. Beef tallow biodiesel blends showed similar trends. Nevertheless, it is important to note that the study measurements are based on low dilution rates and the OC emissions changes may be affected by ambient temperature and different dilution conditions spanning micro-environments and atmospheric conditions. The results show that the use of biodiesel fuel for economic or climate change mitigation purposes can lead to reductions in PM emissions and a co-benefit of EC emission reductions. Detailed speciation of the OC emissions were also examined and are presented to understand the sensitivity of OC emissions with respect to biodiesel fuel blends. Copyright 2012 American Association for Aerosol Research |
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