Formation of Molecular Bromine from the Reaction of Ozone with Deliquesced NaBr Aerosol:  Evidence for Interface Chemistry

Hunt, S. W.; Roeselová, Martina; Wang, W.; Wingen, L. M.; Knipping, Eladio; Tobias, Douglas J.; Dabdub, Donald; Finlayson-Pitts, Barbara J.

doi:10.1021/jp0467346

Cited by 136 publications

(200 citation statements)

References 110 publications

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“…For the formation of molecular chlorine and bromine from aqueous halide aerosols, FinlaysonPitts and coworkers (4,30) have shown that the kinetics model predictions cannot be reconciled with the experimental results unless interfacial reactions are included. Specifically, the amount of molecular bromine formed upon reaction of ozone with the bromide ion in deliquesced sodium bromide aerosols is Ϸ10-fold larger than that predicted by known gas phase and bulk aqueous phase chemistry (30). When an interface reaction was included in the kinetics modeling, the amount of Br 2 formed was reasonably reproduced.…”

Section: Discussionmentioning

confidence: 99%

Partitioning of atmospherically relevant ions between bulk water and the water/vapor interface

Pegram

Record²

2006

Proc. Natl. Acad. Sci. U.S.A.

162

230

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Recently, surface-sensitive spectroscopy data and molecular dynamics simulations have generated intense interest in the distribution of electrolyte ions between bulk water and the air͞water interface. A partitioning model for cations and anions developed for biopolymer surface is extended here to interpret the effects of selected acids, bases, and salts on the surface tension of water. Data for electrolytes were analyzed by using a lower-bound value for the number of water molecules in the surface region [0.2 H 2O Å ؊2 (approximately two layers of water)], obtained by assuming that both Na ؉ and SO 4 2؊ (i.e., Na2SO4) are fully excluded from this region. Surface-bulk partition coefficients of atmospherically relevant anions and the proton are determined. Notably, we find that H ؉ is most strongly surface-accumulated, I ؊ is modestly accumulated, NO 3 ؊ is evenly distributed, and OH ؊ is weakly excluded.surface tension ͉ surface-bulk partition coefficients ͉ inorganic salt ions T he distribution of ions between bulk water and water located at a surface has major implications for processes in biochemistry, atmospheric chemistry, and technology. As early as 1957, the observation of negative surface potentials for aqueous solutions of alkali metal salts of I Ϫ , ClO 4 Ϫ , SCN Ϫ , and PF 6 Ϫ led to the proposal that these anions (but not the cations) were present in the interfacial region of aqueous salt solutions (1, 2). However, the traditional proposal of an ion-free water layer on the surface of salt solutions, based on their positive surface tension increments (d␥͞dm 2 Ͼ 0), went relatively unchallenged until a decade ago, when Hu and coworkers observed that the kinetics of halogen uptake by NaBr and NaI solutions were too rapid to be explained by a simple bulk-phase reaction mechanism (3). The authors concluded that significant concentrations of bromide and iodide must be present in the surface layer, even at low bulk salt concentrations. Since then, considerable attention has been focused on this topic because of its implications for atmospheric chemistry (4, 5). Surface-sensitive spectroscopic experiments (6-9), molecular dynamics simulations (10-12), and various theoretical͞experimental collaborations (13-15) provide evidence, recently reviewed (16), that, although ''hard'' and multiply charged ions are excluded from the surface, large polarizable anions (e.g., SCN Ϫ and I Ϫ ) and the proton accumulate there, in some cases at concentrations greater than in the bulk solution. Only when both ions are hard and͞or multiply charged (e.g., NaF and Na 2 SO 4 ) do the simulations show both ions excluded from the surface, in agreement with the classical picture of a salt-free layer. In other cases, almost complete cationic exclusion and various degrees of anionic accumulation at the surface result in a range of net ion depletion at the surface (13); for these cases, a correspondingly wide range of positive surface tension increments have been reported (17). We apply a recently developed two-state, single-ion partitio...

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Section: Discussionmentioning

confidence: 99%

Partitioning of atmospherically relevant ions between bulk water and the water/vapor interface

Pegram

Record²

2006

Proc. Natl. Acad. Sci. U.S.A.

162

230

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“…113,114 In contrast, the interface oxidation of Br À by O 3 does make a significant contribution to the formation of Br 2 in the dark. [115][116][117] Despite the progress on understanding the structure of salt solutions and the impacts on reactivity, much remains speculative. For example, the (OHÁ Á ÁCl) À complex proposed at the interface has not been observed, and the mechanism by which such a complex forms gaseous Cl 2 is not confirmed.…”

Section: Chemistry At the Interface Of Sea Salt Particlesmentioning

confidence: 99%

Reactions at surfaces in the atmosphere: integration of experiments and theory as necessary (but not necessarily sufficient) for predicting the physical chemistry of aerosols

Finlayson-Pitts

2009

Phys. Chem. Chem. Phys.

231

272

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“…1 However, a combination of computational [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] and experimental studies [16][17][18][19][20][21][22][23][24][25][26][27][28][29][30][31][32][33] has shown that ions can reside and even be enhanced at the interface.…”

Section: Introductionmentioning

confidence: 99%

“…15,16 There is also evidence that the photolysis of species at the interface has higher quantum yields than those in the bulk. [34][35][36][37][38][39][40][41][42][43][44][45][46][47][48] In short, interfacial kinetics and mechanisms may be significantly different compared to those in the bulk phase.…”

Section: Introductionmentioning

confidence: 99%

The effect of cations on NO₂ production from the photolysis of aqueous thin water films of nitrate salts

Richards-Henderson

Anderson

Anastasio

et al. 2015

Phys. Chem. Chem. Phys.

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The photochemistry of nitrate ions in bulk aqueous solution is well known, yet recent evidence suggests that the photolysis of nitrate may be more efficient at the air-water interface. Whether and how this surface enhancement is altered by the presence of different cations is not known. In the present studies, thin aqueous films of nitrate salts with different cations were deposited on the walls of a Teflon chamber and irradiated with 311 nm light at 298 K. The films were generated by nebulizing aqueous 0.5 M solutions of the nitrate salts and the generation of gas-phase NO 2 was monitored with time. The nitrate salts fall into three groups based on their observed rate of NO 2 formation (R NO 2 ): (1) RbNO 3 and KNO 3 , which readily produce NO 2 (R NO 2 4 3 ppb min À1 ), (2) Ca(NO 3 ) 2 , which produces NO 2 more slowly (R NO 2 o 1 ppb min À1 ), and (3) Mg(NO 3 ) 2 and NaNO 3 , which lie between the other two groups. Neither differences in the UV-visible spectra of the nitrate salt solutions nor the results of bulk-phase photolysis studies could explain the differences in the rates of NO 2 production between these three groups. These experimental results, combined with some insights from previous molecular dynamic simulations and vibrational sum frequency generation studies, show that cations may impact the concentration of nitrate ions in the interface region, thereby directly impacting the effective quantum yields for nitrate ions.

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Formation of Molecular Bromine from the Reaction of Ozone with Deliquesced NaBr Aerosol: Evidence for Interface Chemistry

Cited by 136 publications

References 110 publications

Partitioning of atmospherically relevant ions between bulk water and the water/vapor interface

Partitioning of atmospherically relevant ions between bulk water and the water/vapor interface

Reactions at surfaces in the atmosphere: integration of experiments and theory as necessary (but not necessarily sufficient) for predicting the physical chemistry of aerosols

The effect of cations on NO₂ production from the photolysis of aqueous thin water films of nitrate salts

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Formation of Molecular Bromine from the Reaction of Ozone with Deliquesced NaBr Aerosol: Evidence for Interface Chemistry

Cited by 136 publications

References 110 publications

Partitioning of atmospherically relevant ions between bulk water and the water/vapor interface

Partitioning of atmospherically relevant ions between bulk water and the water/vapor interface

Reactions at surfaces in the atmosphere: integration of experiments and theory as necessary (but not necessarily sufficient) for predicting the physical chemistry of aerosols

The effect of cations on NO2 production from the photolysis of aqueous thin water films of nitrate salts

Contact Info

Product

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About

The effect of cations on NO₂ production from the photolysis of aqueous thin water films of nitrate salts