SIMULTANEOUS GAS-PHASE AND SURFACE ATOM RECOMBINATION FOR STAGNATION BOUNDARY LAYER

Abstract. The cycling of inorganic bromine in the marine boundary layer (mbl) has received increased attention in recent years. Bromide, a constituent of sea water, is injected into the atmosphere in association with sea-salt aerosol by breaking waves on the ocean surface. Measurements reveal that supermicrometer sea-salt aerosol is depleted in bromine by about 50% relative to conservative tracers, whereas marine submicrometer aerosol is often enriched in bromine. Model calculations, laboratory studies, and field observations strongly suggest that these depletions reflect the chemical transformation of particulate bromide to reactive inorganic gases that influence the processing of ozone and other important constituents of marine air. However, currently available techniques cannot reliably quantify many \\chem{Br}-containing compounds at ambient concentrations and, consequently, our understanding of inorganic Br cycling over the oceans and its global significance are uncertain. To provide a more coherent framework for future research, we have reviewed measurements in marine aerosol, the gas phase, and in rain. We also summarize sources and sinks, as well as model and laboratory studies of chemical transformations. The focus is on inorganic bromine over the open oceans, excluding the polar regions. The generation of sea-salt aerosol at the ocean surface is the major tropospheric source producing about 6.2 Tg/a of bromide. The transport of Br from continents (as mineral aerosol, and as products from biomass-burning and fossil-fuel combustion) can be of local importance. Transport of degradation products of long-lived Br-containing compounds from the stratosphere and other sources contribute lesser amounts. Available evidence suggests that, following aerosol acidification, sea-salt bromide reacts to form Br2 and BrCl that volatilize to the gas phase and photolyze in daylight to produce atomic Br and Cl. Subsequent transformations can destroy tropospheric ozone, oxidize dimethylsulfide (DMS) and hydrocarbons in the gas phase and S(IV) in aerosol solutions, and thereby potentially influence climate. The diurnal cycle of gas-phase \\Br and the corresponding particulate Br deficits are correlated. Higher values of Br in the gas phase during daytime are consistent with expectations based on photochemistry. Mechanisms that explain the widely reported accumulation of particulate Br in submicrometer aerosols are not yet understood. We expect that the importance of inorganic Br cycling will vary in the future as a function of both increasing acidification of the atmosphere (through anthropogenic emissions) and climate changes. The latter affects bromine cycling via meteorological factors including global wind fields (and the associated production of sea-salt aerosol), temperature, and relative humidity.

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Modelling multi-phase halogen chemistry in the remote marine boundary layer: investigation of the influence of aerosol size resolution on predicted gas- and condensed-phase chemistry

Atmospheric Chemistry and Physics Discussions ◽

10.5194/acpd-9-5289-2009 ◽

2009 ◽

Vol 9 (2) ◽

pp. 5289-5320 ◽

Cited By ~ 1

Author(s):

D. Lowe ◽

D. Topping ◽

G. McFiggans

Keyword(s):

Boundary Layer ◽

Gas Phase ◽

Condensed Phase ◽

Significant Influence ◽

Marine Boundary Layer ◽

Turnover Rates ◽

Gas Phase Chemistry ◽

Size Dependent ◽

Multi Phase ◽

Phase Chemistry

Abstract. A coupled box model of photochemistry and aerosol microphysics which explicitly accounts for size-dependent chemical properties of the condensed-phase has been developed to simulate the multi-phase chemistry of chlorine, bromine and iodine in the marine boundary layer (MBL). The model contains separate seasalt and non-seasalt modes, each of which may be composed of 1–16 size-sections. By comparison of gaseous and aerosol compositions predicted using different size-resolutions with both fixed and size-dependent aerosol turnover rates, it was found that, for halogen-activation processes, the physical property initialisation of the aerosol-mode has a significant influence on gas-phase chemistry. Failure to adequately represent the appropriate physical properties can lead to substantial errors in gas-phase chemistry. The size-resolution of condensed-phase composition has a less significant influence on gas-phase chemistry.

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Modeling of the Convective Thermal Ignition Process of Solid Fuel Particles

Journal of Heat Transfer ◽

10.1115/1.2910511 ◽

1990 ◽

Vol 112 (4) ◽

pp. 995-1001 ◽

Cited By ~ 3

Author(s):

Jing-Tang Yang ◽

Gwo-Guang Wang ◽

Hung-Yi Li

Keyword(s):

Boundary Layer ◽

Gas Phase ◽

Azimuthal Angle ◽

Ignition Process ◽

Thermal Ignition ◽

Boundary Layer Equations ◽

Runge Kutta Method ◽

Convective Thermal ◽

Dimensional Boundary ◽

Fuel Particles

This work uses the boundary layer theory to study the thermal ignition process of the solid particle. The theoretical model explores the two-dimensional boundary layer equations in the gaseous phase. The governing equations of mass, momentum, energy, and species in gas phase are first transformed to ordinary differential equations through series expansion with respect to the azimuthal angle. The equations are then quasi-linearized to be the initial value problem and solved using Runge-Kutta method. The minimum heat flux from the gas phase to the fuel is evaluated as the most suitable criterion for the convective thermal ignition. The influences of the heat transfer rate, fluid dynamics, and the gas phase chemical reaction rate on the ignition delay and ignition position are discussed in detail.

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Radicals in the marine boundary layer during NEAQS 2004: a model study of day-time and night-time sources and sinks

Atmospheric Chemistry and Physics ◽

10.5194/acp-9-3075-2009 ◽

2009 ◽

Vol 9 (9) ◽

pp. 3075-3093 ◽

Cited By ~ 24

Author(s):

R. Sommariva ◽

H. D. Osthoff ◽

S. S. Brown ◽

T. S. Bates ◽

T. Baynard ◽

...

Keyword(s):

Boundary Layer ◽

New England ◽

Gas Phase ◽

Marine Boundary Layer ◽

Peroxy Radical ◽

Chemical Mechanism ◽

Physical Parameters ◽

Peroxy Radicals ◽

Night Time ◽

Aerosol Composition

Abstract. This paper describes a modelling study of several HOx and NOx species (OH, HO2, organic peroxy radicals, NO3 and N2O5) in the marine boundary layer. A model based upon the Master Chemical Mechanism (MCM) was constrained to observations of chemical and physical parameters made onboard the NOAA ship R/V Brown as part of the New England Air Quality Study (NEAQS) in the summer of 2004. The model was used to calculate [OH] and to determine the composition of the peroxy radical pool. Modelled [NO3] and [N2O5] were compared to in-situ measurements by Cavity Ring-Down Spectroscopy. The comparison showed that the model generally overestimated the measurements by 30–50%, on average. The model results were analyzed with respect to several chemical and physical parameters, including uptake of NO3 and N2O5 on fog droplets and on aerosol, dry deposition of NO3 and N2O5, gas-phase hydrolysis of N2O5 and reactions of NO3 with NMHCs and peroxy radicals. The results suggest that fog, when present, is an important sink for N2O5 via rapid heterogeneous uptake. The comparison between the model and the measurements were consistent with values of the heterogeneous uptake coefficient of N2O5 (γN2O5)>1×10−2, independent of aerosol composition in this marine environment. The analysis of the different loss processes of the nitrate radical showed the important role of the organic peroxy radicals, which accounted for a significant fraction (median: 15%) of NO3 gas-phase removal, particularly in the presence of high concentrations of dimethyl sulphide (DMS).

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Organic nitrate chemistry and its implications for nitrogen budgets in an isoprene- and monoterpene-rich atmosphere: constraints from aircraft (SEAC<sup>4</sup>RS) and ground-based (SOAS) observations in the Southeast US

Atmospheric Chemistry and Physics ◽

10.5194/acp-16-5969-2016 ◽

2016 ◽

Vol 16 (9) ◽

pp. 5969-5991 ◽

Cited By ~ 89

Author(s):

Jenny A. Fisher ◽

Daniel J. Jacob ◽

Katherine R. Travis ◽

Patrick S. Kim ◽

Eloise A. Marais ◽

...

Keyword(s):

Boundary Layer ◽

Gas Phase ◽

Transport Model ◽

Oxidation Mechanism ◽

Organic Nitrate ◽

Organic Nitrates ◽

Nox Emissions ◽

Particle Phase ◽

Chemical Transport Model ◽

Southeast Us

Abstract. Formation of organic nitrates (RONO2) during oxidation of biogenic volatile organic compounds (BVOCs: isoprene, monoterpenes) is a significant loss pathway for atmospheric nitrogen oxide radicals (NOx), but the chemistry of RONO2 formation and degradation remains uncertain. Here we implement a new BVOC oxidation mechanism (including updated isoprene chemistry, new monoterpene chemistry, and particle uptake of RONO2) in the GEOS-Chem global chemical transport model with ∼  25  ×  25 km2 resolution over North America. We evaluate the model using aircraft (SEAC4RS) and ground-based (SOAS) observations of NOx, BVOCs, and RONO2 from the Southeast US in summer 2013. The updated simulation successfully reproduces the concentrations of individual gas- and particle-phase RONO2 species measured during the campaigns. Gas-phase isoprene nitrates account for 25–50 % of observed RONO2 in surface air, and we find that another 10 % is contributed by gas-phase monoterpene nitrates. Observations in the free troposphere show an important contribution from long-lived nitrates derived from anthropogenic VOCs. During both campaigns, at least 10 % of observed boundary layer RONO2 were in the particle phase. We find that aerosol uptake followed by hydrolysis to HNO3 accounts for 60 % of simulated gas-phase RONO2 loss in the boundary layer. Other losses are 20 % by photolysis to recycle NOx and 15 % by dry deposition. RONO2 production accounts for 20 % of the net regional NOx sink in the Southeast US in summer, limited by the spatial segregation between BVOC and NOx emissions. This segregation implies that RONO2 production will remain a minor sink for NOx in the Southeast US in the future even as NOx emissions continue to decline.

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Gas-phase boundary layer ignition on a catalytic flat plate with heat loss

Combustion and Flame ◽

10.1016/0010-2180(85)90071-9 ◽

1985 ◽

Vol 61 (1) ◽

pp. 39-49 ◽

Cited By ~ 22

Author(s):

C. Trevino ◽

N. Peters

Keyword(s):

Boundary Layer ◽

Phase Boundary ◽

Flat Plate ◽

Gas Phase ◽

Heat Loss

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Self-limited growth of InAs at 480 °C

Journal of Materials Research ◽

10.1557/jmr.1994.3022 ◽

1994 ◽

Vol 9 (12) ◽

pp. 3022-3024 ◽

Cited By ~ 2

Author(s):

D. Jung ◽

S.M. Bedair

Keyword(s):

Boundary Layer ◽

Gas Phase ◽

The Self ◽

Phase Decomposition ◽

Limited Growth

Self-limited growth of InAs at 480 °C is achieved by a rotating substrate method with a specially designed susceptor. The residual precursors and the boundary layer are removed by the mechanical shear-off. Prevention of the precursor carryover and the gas-phase decomposition are thought to result in the self-limited growth of InAs at temperatures as high as 480 °C.

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Modeling of daytime HONO vertical gradients during SHARP 2009

Atmospheric Chemistry and Physics Discussions ◽

10.5194/acpd-12-27775-2012 ◽

2012 ◽

Vol 12 (10) ◽

pp. 27775-27819

Author(s):

K. W. Wong ◽

C. Tsai ◽

B. Lefer ◽

N. Grossberg ◽

J. Stutz

Keyword(s):

Boundary Layer ◽

Gas Phase ◽

Rural Areas ◽

Transport Model ◽

Vertical Transport ◽

Formation Mechanisms ◽

Aerosol Model ◽

Formation Pathway ◽

Sensitivity Studies ◽

Urban And Rural Areas

Abstract. Nitrous Acid (HONO) acts as a major precursor of the hydroxyl radical (OH) in the urban atmospheric boundary layer in the morning and throughout the day. Despite its importance, HONO formation mechanisms are not yet completely understood. It is generally accepted that conversion of NO2 on surfaces in the presence of water is responsible for the formation of HONO in the nocturnal boundary layer, although the type of surface on which the mechanism occurs is still under debate. Recent observations of higher than expected daytime HONO concentrations in both urban and rural areas indicate the presence of unknown daytime HONO source(s). Various formation pathways in the gas-phase and on aerosol and ground surfaces have been proposed to explain the presence of daytime HONO. However, it is unclear which mechanism dominates and, in the cases of heterogeneous mechanisms, on which surfaces they occur. Vertical concentration profiles of HONO and its precursors can help in identifying the dominant HONO formation pathways. In this study, daytime HONO and NO2 vertical profiles, measured in three different height intervals (20–70 m, 70–130 m and 130–300 m) in Houston, TX during the 2009 Study of Houston Atmospheric Radical Precursors (SHARP) are analyzed using a one-dimensional (1-D) chemistry and transport model. Model results with various HONO formation pathways suggested in the literature are compared to the the daytime HONO and HONO/NO2 ratios observed during SHARP. The best agreement of HONO and HONO/NO2 ratios between model and observations is achieved by including both a photolytic source of HONO at the ground and on the aerosol. Model sensitivity studies show that the observed diurnal variations of HONO/NO2 ratio are not reproduced by the model if there is only a photolytic HONO source on aerosol or in the gas-phase from NO2* + H2O. Further analysis of the formation and loss pathways of HONO shows a vertical dependence of HONO chemistry during the day. Photolytic HONO formation at the ground is the major formation pathway in the lowest 20 m, while a combination of gas-phase, photolytic formation on aerosol, and vertical transport is responsible for daytime HONO between 200–300 m a.g.l. HONO removal is dominated by vertical transport below 20 m and photolysis between 200–300 m a.g.l.

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