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Journal of Nanoparticle Research

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01.11.2012 | Research Paper

Microscopic investigation of soot and ash particulate matter derived from biofuel and diesel: implications for the reactivity of soot

verfasst von: Anthi Liati, Alexander Spiteri, Panayotis Dimopoulos Eggenschwiler, Nina Vogel-Schäuble

Erschienen in: Journal of Nanoparticle Research | Ausgabe 11/2012

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Abstract

Investigation of soot and ash particulate matter deposited in diesel particulate filters (DPFs) operating with biofuel (B100) and diesel (pure diesel: B0 and diesel₈₀/biofuel₂₀ blend: B20) by means of optical microscopy, scanning electron microscopy, and high resolution transmission electron microscopy (HRTEM) reveals the following: the rapeseed methyl ester biofuel used for this study contributes to ash production, mainly of Ca–S– and P-bearing compounds ranging in size between 50 and 300 nm. Smaller ash particles are less common and build aggregates. Ash is deposited on the inlet DPF surface, the inlet channel walls, and in B100-DPF at the plugged ends of inlet channels. The presence of Fe–Cr–Ni fragments, down to tens of nanometers in size within the ash is attributed to engine wear. Pt particles (50–400 nm large) within the ash indicate that the diesel oxidation catalyst (DOC) upstream of the DPF shows aging effects. Radial cracks on the coating layer of the DOC confirm this assumption. The B100-DPF contains significantly less soot than B20 and B0. Based on the generally accepted view that soot reactivity correlates with the nanostructure of its primary particles, the length and curvature of graphene sheets from biofuel- and diesel-derived soot were measured and computed on the basis of HRTEM images. The results show that biofuel-derived soot can be more easily oxidized than diesel soot, not only during early formation but also during and after considerable particle growth. Differences in the graphene sheet separation distance, degree of crystalline order and size of primary soot particles between the two fuel types are in line with this inference.

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Agarwal AK (2007) Biofuels (alcohols and biodiesel) applications as fuels for internal combustion engines. Prog Energy Combust Sci 33:233–271CrossRef

Bensaid S, Marchisio DI, Russo N, Fino D (2009) Experimental investigation of soot deposited in diesel particulate filters. Catal Today 147:S295–S300CrossRef

Boehman AL, Song J, Alam M (2005) Impact of biodiesel blending on diesel soot and the regeneration of particulate filters. Energy Fuels 19:1857–1864CrossRef

Britton N, Sutton M, Otterholm B, Tengstrom P, Frennfelt C, Walker A, Murray I (2004) Investigations into lubricant blocking of diesel particulate filters. SAE Technical Paper 2004-01-3013

Cataldo F (2002) The impact of fullerene-like concept in carbon black science. Carbon 40:157–162CrossRef

Hays MD, Vander Wal RL (2007) Heterogeneous soot nanostructure in atmospheric and combustion source aerosols. Energy Fuels 21:801–811CrossRef

Jung H, Kittelson DB, Zachariah MR (2006) Characteristics of SME biodiesel-fueled diesel particle emissions and the kinetics of oxidation. Environ Sci Technol 40(16):4949–4955CrossRef

Kim DH, Wang CH (2007) HRTEM Study of diesel soot collected from diesel particulate filters. Carbon 45:70–77CrossRef

Knauer M, Schuster ME, Su D, Schlögl R, Niessner R, Ivleva NP (2009) Soot structure and reactivity analysis by Raman microspectroscopy, temperature-programmed oxidation, and high-resolution transmission electron microscopy. J Phys Chem A 113:13871–13880CrossRef

Knothe G (2008) ‘Designer’ biodiesel: optimizing fatty ester composition to improve fuel properties. Energy Fuels 22:1358–1364CrossRef

Lamharess N, Millet CN, Starck L, Jeudy E, Lavy J, Da Costa P (2011) Catalysed diesel particulate filter: study of the reactivity of soot arising from biodiesel combustion. Catal Today 176:219–224CrossRef

Lapuerta M, Armas O, Rodríguez-Fernández J (2008) Effect of biodiesel fuels on diesel engine emissions. Prog Energy Combust Sci 34:198–223CrossRef

Liati A, Dimopoulos Eggenschwiler P (2010) Characterisation of particulate matter deposited in diesel particulate filters: visual and analytical approach in macro-, micro- and nano-scales. Combust Flame 157:1658–1670CrossRef

Liati A, Dimopoulos Eggenschwiler P, Czerwinski J, Bonsack P, Hermle S (2011) Comparative studies of particles deposited in diesel particulate filters operating with biofuel, diesel fuel and fuel blends. SAE Technical Paper 2011-24-0102

Liati A, Dimopoulos Eggenschwiller P, Müller Gubler E, Schreiber D, Aguirre M (2012) Investigation of diesel ash particulate matter: a scanning electron microscope and transmission electron microscope study. Atmos Environ 49:391–402CrossRef

Müller JO, Su DS, Jentoft RE, Kröhnert J, Jentoft FC, Schlögl R (2005) Morphology-controlled reactivity of carbonaceous materials towards oxidation. Catal Today 102(103):259–265CrossRef

Müller JO, Su DS, Jentoft RE, Wild U, Schlögl R (2006) Diesel engine exhaust emission: oxidative behavior and microstructure of black smoke soot particulate. Environ Sci Technol 40:1231–1236CrossRef

Müller JO, Su DS, Wild U, Schlögl R (2007) Bulk and surface structural investigations of diesel engine soot and carbon black. Phys Chem Chem Phys 9:4018–4025CrossRef

Nishi K, Korematsu K, Tanaka J (2004) Potential of rapeseed oil as diesel engine fuel. SAE Technical Paper 2004-01-1858

Rakopoulos CD, Rakopoulos DC, Hountalas DT, Giakoumis EG, Andritsakis EC (2008) Performance and emissions of bus engine using blends of diesel fuel with bio-diesel of sunflower or cottonseed oils derived from Greek feedstocks. Fuel 87:147–157CrossRef

Sappok A, Wong V (2010) Ash effects on diesel particulate filter pressure drop sensitivity to soot and implications for regeneration frequency and DPF control. SAE Int J Fuels Lubr 3:380–396

Schreiber D, Forss A M, Mohr M and Dimopoulos P (2007) Particle characterisation of modern CNG, gasoline and diesel passenger cars. SAE (Society of Automotive Engineers) Paper 2007-24-0123, Italy

Schuster ME, Hävecker M, Arrigo R, Blume R, Knauer M, Ivleva NP, Su DS, Niessner R, Schlögl R (2011) Surface sensitive study to determine the reactivity of soot with the focus on the European emission standards IV and VI. J Phys Chem A 115:2568–2580CrossRef

Song J, Alam AL, Boehman U, Kim U (2006) Examination of the oxidation behavior of biodiesel soot. Combust Flame 146:589–604CrossRef

Song J, Alam M, Boehman AL (2007) Impact of alternative fuels on soot properties and DPF regeneration. Combust Sci Technol 179:1991–2037CrossRef

Su DS, Jentoft RE, Müller JO, Jentoft RE, Rothe D, Jacob E, Schlögl R (2004a) Fullerene-like soot from Euro-IV diesel engine: consequences for catalytic automotive pollution control. Top Catal 30(31):241–245CrossRef

Su DS, Jentoft RE, Müller JO, Rothe D, Jacob E, Simpson CD et al (2004b) Microstructure and oxidation behaviour of Euro IV diesel engine soot: a comparative study with synthetic model soot substances. Catal Today 90:127–132CrossRef

Tsolakis A, Megaritis A, Wyszynski ML, Theinno K (2007) Engine performance and emissions of a diesel engine operating on diesel-RME (rapeseed methyl ester) blends with EGR (exhaust gas recirculation). Energy 32:2072–2080CrossRef

Twigg MV (2007) Progress and future challenges in controlling automotive exhaust gas emissions. Appl Catal B 70:2–15CrossRef

Vaaraslahti K, Keskinen J, Giechaskiel B, Solla A, Murtonen T, Vesala H (2005) Effect of lubricant on the formation of heavy-duty diesel exhaust nanoparticles. Environ Sci Technol 39:8497–8504CrossRef

Vander Wal RL, Tomasek AJ, Pamphlet MI, Taylor CD, Thompson WK (2004) Analysis of HRTEM images for carbon nanostructure quantification. J Nanopart Res 6:555–568CrossRef

Vander Wal RL, Bryg VM, Hays MD (2010) Fingerprinting soot (towards source identification): physical structure and chemical composition. Aerosol Sci 41:108–117CrossRef

Wang WG, Lyons DW, Clark NN, Gautam M, Norton PM (2000) Emissions from nine heavy trucks fuelled by diesel and biodiesel blend without engine modification. Environ Sci Technol 34(6):933–939CrossRef

Watson SAG (2010) Lubricant-derived ash—in engine sources and opportunities for reduction. PhD Thesis, Massachusetts Institute of Technology, 235 pp

Wu F, Wang J, Chen W, Shuai S (2008) Effects of different biodiesels and their blends with oxygenated additives on emissions from a diesel engine. SAE Technical Paper 2008-01-1812

Yehliu K, Vander Wal RL, Boehman AL (2011) Development of an HRTEM image analysis method to quantify carbon nanostructure. Combust Flame 158:1837–1851CrossRef

Yezerets A, Currier NW, Eadler HA, Suresh A, Madden PF (2003) Investigation of the oxidation behavior of diesel particulate matter. Catal Today 88:17–25CrossRef

Zabetta E, Hupa M, Niemi S (2006) Bio-derived fuels may ease the regeneration of diesel particulate traps. Fuel 85:2666–2670CrossRef

Zhu W, Miser DE, Geoffrey Chan W, Hajaligol MR (2004) Characterisation of combustion fullerene soot, C₆₀, and mixed fullerene. Carbon 42:1463–1471CrossRef

Titel: Microscopic investigation of soot and ash particulate matter derived from biofuel and diesel: implications for the reactivity of soot
verfasst von: Anthi Liati
Alexander Spiteri
Panayotis Dimopoulos Eggenschwiler
Nina Vogel-Schäuble
Publikationsdatum: 01.11.2012
Verlag: Springer Netherlands
Erschienen in: Journal of Nanoparticle Research / Ausgabe 11/2012
Print ISSN: 1388-0764
Elektronische ISSN: 1572-896X
DOI: https://doi.org/10.1007/s11051-012-1224-7

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