Fast and quantitative measurement of benzene, toluene and C-2-benzenes in automotive exhaust during transient engine operation with and without catalytic exhaust gas treatment

Time-Resolved Chemical Ionization Mass Spectrometry (CIMS) has been used to investigate the emission profiles of benzene, toluene and the C-2-benzenes (xylenes and ethyl benzene) in automotive exhaust during transient engine operation. On-line emission measurements with a frequency of 1-5 Hz clearly identified the critical driving conditions that are mainly responsible for the overall aromatic hydrocarbon emissions. The passenger car, equipped wi th a catalytic converter showed significant BTXE-emissions only in the firs t part of the New European Driving Cycle (NEDC) due to sub-optimal catalyst temperature. On the same car without a catalytic converter, emissions of a romatic hydrocarbons were detected over the entire test run and the benzene -toluene mixing ratios of the exhaust gas were rather constant. With cataly tic exhaust gas treatment the observed benzene-toluene mixing ratios varied to a greater extent reflecting predominantly different catalytic converter conditions. The average molar ratio of benzene over toluene rose from 0.33 to 0.53 upon exhaust gas treatment. With catalytic converter the emissions during extra urban (EUDC) driving repeatedly showed benzene-toluene mixing ratios >1 and an average molar benzene/toluene ratio of 0.74 was detected during the EUDC part of the driving cycle. Whereas the total hydrocarbon (T .HC) emissions were decreased by 83% upon exhaust gas treatment the overall reduction of the benzene emissions was only 70%. (C) 1998 Elsevier Science Ltd. All rights reserved.