Heterogeneous Reaction of NO2on Diesel Soot Particles

Abstract

Soot particles were collected from a diesel engine using a procedure that realistically mimics exhaust gas conditions in tailpipes and during dilution at room temperature. After being sampled, the particles were exposed to NO₂ concentrations and relative humidity in ranges relevant for the troposphere using ¹³N as tracer. Gas-phase nitrous acid (HONO) and irreversibly bound (i.e., chemisorbed) species were the main reaction products with initial yields of 80−90% and about 10%, respectively. Neither NO nor HNO₃ were detectable. The HONO formation increased with increasing engine load (i.e., with a decreasing air to fuel ratio, λ). The reaction rates of HONO and chemisorbed NO₂ increased with increasing NO₂ concentration and did not depend on relative humidity. At the beginning of reaction, the uptake coefficient averaged over 3 min ranged from 5 × 10^-6 to 10^-5 for NO₂ concentrations between 2 and 40 ppb. The HONO formation rates decreased with time, indicating consumption of reactive surface species, while the chemisorption rates remained almost constant. The total HONO formation potential of the particles was estimated to about 1.3 × 10¹⁷ molecules/mg of diesel soot or to about 4.7 mg/kg of diesel fuel, indicating that the reaction between NO₂ and diesel soot particles does not provide a significant secondary HONO source in the atmosphere. A Langmuir−Hinshelwood type reaction mechanism was proposed that adequately describes the observed results and also allows discussing important general features of reactions on soot.