Quantification of the unknown HONO daytime source and its relation to NO<sub>2</sub>

Abstract: Abstract. During the DOMINO (Diel Oxidant MechanismIn relation to Nitrogen Oxides) campaign in southwest Spain we measured simultaneously all quantities necessary to calculate a photostationary state for HONO in the gas phase. These quantities comprise the concentrations of OH, NO, and HONO and the photolysis frequency of NO 2 , j (NO 2 ) as a proxy for j (HONO). This allowed us to calculate values of the unknown HONO daytime source. This unknown HONO source, normalized by NO 2 mixing ratios and expressed as a… Show more

“…48 We then review and summarize pertinent information on aerosol optical depth time series data over megacities, 49,50 and solar photolysis frequencies J(NO 2 ), J(O 1 D) and J(HONO) as functions of season and latitude. 20 On this factual basis, we provide a novel interpretation of recently reported data on the quantication of the unknown HONO daytime source, 26 and seasonally-averaged daytime NO 2 decay lifetimes over several megacities. 51 …”

“…93 However, recent work has provided strong constraints on the unknown HONO daytime source and its relation to NO 2 chemistry. 26 Key ndings were that the rates of HONO production during daytime, R HONO , at a given site (1) are an order of magnitude faster than extrapolated nighttime rates of the hydrolytic disproportionation of NO 2 on wet surfaces, 27 (2) systematically increase with solar ux, peaking at noon but, however, (3) can be accounted neither by the reaction of excited NO 2 * with H 2 O(g), 28 reaction R9 nor by the reduction of NO 2 photosensitized by irradiated soot, [C-H] red *, reaction R10: 46,94 …”

“…26 Since a 50% NO 2 / HONO conversion is the stoichiometric limit imposed by R1, the implication is that the 'unknown HONO daytime source' must also be a signicant daytime sink (as NO 3 À ) for NO 2 , and should therefore impact NO 2 decay lifetimes. At present, it is not obvious how the heterogeneous 'dark' reaction R1 could be signicantly enhanced by sunlight, 26 or whether such enhancements are compatible with the kinetics of NO 2 removal, 95 which is generally deemed to occur exclusively in the gas-phase via reaction R11:…”

“…25 Given the key role of _OH, this represents a major deciency in our understanding of tropospheric chemistry. It has been suggested that the diminished solar photolysis of O 3 in winter could be supplemented by that of HONO, 16,[26][27][28][29][30] reaction R6,…”

“…97 Thus, by adopting a representative average value for the uptake coefficient of NO 2 (g) on tropospheric aerosols: g $ 3 Â 10 À4 (see above), we estimate k d $ 6 Â 10 À5 s À1 , which corresponds to $20% NO 2 (g) hourly conversions in clear-day conditions, i.e., in the range of those observed in the eld. 26 By assuming that all HONO produced in reaction R1 is rapidly photolyzed via R6, the rate of _OH production at the terminus of this route, r +OH (R1), will therefore be given by eqn (E3):…”

Tropospheric aerosol as a reactive intermediate

“…48 We then review and summarize pertinent information on aerosol optical depth time series data over megacities, 49,50 and solar photolysis frequencies J(NO 2 ), J(O 1 D) and J(HONO) as functions of season and latitude. 20 On this factual basis, we provide a novel interpretation of recently reported data on the quantication of the unknown HONO daytime source, 26 and seasonally-averaged daytime NO 2 decay lifetimes over several megacities. 51 …”

“…93 However, recent work has provided strong constraints on the unknown HONO daytime source and its relation to NO 2 chemistry. 26 Key ndings were that the rates of HONO production during daytime, R HONO , at a given site (1) are an order of magnitude faster than extrapolated nighttime rates of the hydrolytic disproportionation of NO 2 on wet surfaces, 27 (2) systematically increase with solar ux, peaking at noon but, however, (3) can be accounted neither by the reaction of excited NO 2 * with H 2 O(g), 28 reaction R9 nor by the reduction of NO 2 photosensitized by irradiated soot, [C-H] red *, reaction R10: 46,94 …”

“…26 Since a 50% NO 2 / HONO conversion is the stoichiometric limit imposed by R1, the implication is that the 'unknown HONO daytime source' must also be a signicant daytime sink (as NO 3 À ) for NO 2 , and should therefore impact NO 2 decay lifetimes. At present, it is not obvious how the heterogeneous 'dark' reaction R1 could be signicantly enhanced by sunlight, 26 or whether such enhancements are compatible with the kinetics of NO 2 removal, 95 which is generally deemed to occur exclusively in the gas-phase via reaction R11:…”

“…25 Given the key role of _OH, this represents a major deciency in our understanding of tropospheric chemistry. It has been suggested that the diminished solar photolysis of O 3 in winter could be supplemented by that of HONO, 16,[26][27][28][29][30] reaction R6,…”

“…97 Thus, by adopting a representative average value for the uptake coefficient of NO 2 (g) on tropospheric aerosols: g $ 3 Â 10 À4 (see above), we estimate k d $ 6 Â 10 À5 s À1 , which corresponds to $20% NO 2 (g) hourly conversions in clear-day conditions, i.e., in the range of those observed in the eld. 26 By assuming that all HONO produced in reaction R1 is rapidly photolyzed via R6, the rate of _OH production at the terminus of this route, r +OH (R1), will therefore be given by eqn (E3):…”

Tropospheric aerosol as a reactive intermediate

Urban measurements of atmospheric nitrous acid: A caveat on the interpretation of the HONO photostationary state

Evidence for a nitrous acid (HONO) reservoir at the ground surface in Bakersfield, CA, during CalNex 2010