Ionization of Nitric Acid on Ice

Pursell, Christopher J.; Everest, Michael A.; Falgout, Mary E.; Sanchez, Diana D.

doi:10.1021/jp025697k

Cited by 22 publications

(43 citation statements)

References 26 publications

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“…However, some observational evidence suggests that the physically driven loss of molecular HNO 3 from the snow matrix is a slow process. Dissolution of HNO 3 and therefore also release across the air-QLL interface was observed to occur within minutes (Pursell et al, 2002). But on the snow grain scale, HNO 3 diffusion measured in ice is too slow to explain rapid loss of NO (Thibert and Domine, 1998) and yields for typical snow grain diameters d of 0.05-0.1 cm an average diffusion time τ=d 2 (2 D 0 ) −1 of 1.5-3 yr.…”

Section: Evaporationmentioning

confidence: 97%

“…Regarding the chemical form we know that in present-day Antarctica and past interglacials NO − 3 occurs predominantly as HNO 3 as opposed to the salt Ca(NO 3 ) 2 during glacials (Legrand et al, 1999). It has been suggested that HNO 3 newly adsorbed on ice ionizes in a 2-step process, HNO (Pursell et al, 2002). Molecular dynamics simulations provide support for the notion that nitrate at the air-water interface remains molecular HNO 3 , whereas it dissociates when embedded at various depths within the aqueous layer (e.g.…”

Section: Mechanisms Of Isotopic Fractionation In Snowmentioning

confidence: 99%

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Photolytic control of the nitrate stable isotope signal in snow and atmosphere of East Antarctica and implications for reactive nitrogen cycling

Frey¹,

Savarino²,

Morin³

et al. 2009

Preprint

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Abstract. The nitrogen (δ15N) and triple oxygen (δ17/18O) isotopic composition of nitrate (NO3−) was measured year-round in the atmosphere and snow pits at Dome C (DC, 75.1° S, 123.3° E), and in surface snow on a transect between DC and the coast. Snow pit profiles of δ15N (δ18O) in NO3− show significant enrichment (depletion) of >200 (<40) ‰ compared to the isotopic signal in atmospheric NO3−, whereas post-depositional fractionation in Δ17O(NO3−) is small, allowing reconstruction of past shifts in tropospheric oxidation pathways from ice cores. Assuming a Rayleigh-type process we find in the DC04 (DC07) pit fractionation factors ε of −50±10 (−71±12) ‰, 6±3 (9±2) ‰ and 1±0.2 (2±0.6) ‰, for δ15N, δ18O and Δ17O, respectively. A photolysis model reproduces ε for δ15N within the range of uncertainty at DC and for lab experiments reported by Blunier et al. (2005), suggesting that the current literature value for photolytic isotopic fractionation in snow is significantly underestimated. Depletion of oxygen stable isotopes is attributed to photolysis followed by isotopic exchange with water and hydroxyl radicals. Conversely, 15N enrichment of the NO3− fraction in the snow implies 15N depletion of emissions. Indeed, δ15N in atmospheric NO3− shows a strong decrease from background levels (4.4±6.8‰) to −35.1‰ in spring followed by recovery during summer, consistent with significant snow pack emissions of reactive nitrogen. Field and lab evidence therefore suggest that photolysis dominates fractionation and associated NO3− loss from snow in the low-accumulation regions of the East Antarctic Ice Sheet (EAIS). The Δ17O signature confirms previous coastal measurements that the peak of atmospheric NO3− in spring is of stratospheric origin. After sunrise photolysis drives then redistribution of NO3− from the snowpack photic zone to the atmosphere and a snow surface skin layer, thereby concentrating NO3− at the surface. Little NO3− is exported off the EAIS plateau, still snow emissions from as far as 600 km inland can contribute to the coastal NO3− budget.

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Section: Evaporationmentioning

confidence: 97%

Section: Mechanisms Of Isotopic Fractionation In Snowmentioning

confidence: 99%

Photolytic control of the nitrate stable isotope signal in snow and atmosphere of East Antarctica and implications for reactive nitrogen cycling

Frey¹,

Savarino²,

Morin³

et al. 2009

Preprint

View full text Add to dashboard Cite

show abstract

“…This explained that evaporative losses were lowest for highly dissociated acids such as hydrochloric acid (HCl) and not detectable for HNO 3 during 96 h long experiments (Sato et al, 2008). However, in another study dissolution of HNO 3 and therefore also release across the air-QLL interface was observed to occur within minutes (Pursell et al, 2002). Thus, from a thermodynamic point of view it is conceivable that temperature-dependent adsorption and desorption contributes to NO − 3 loss from snow at DC.…”

Section: Evaporationmentioning

confidence: 98%

“…where subscripts g, s, ad and aq denote gas, surface, adsorbed and solvated (aqueous) species, respectively (Pursell et al, 2002). Evaporation requires then just reversing Reaction (R6).…”

Section: Mechanisms Of Isotopic Fractionation In Snowmentioning

confidence: 99%

Photolysis imprint in the nitrate stable isotope signal in snow and atmosphere of East Antarctica and implications for reactive nitrogen cycling

et al. 2009

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) is small, potentially allowing reconstruction of past shifts in tropospheric oxidation pathways from ice cores. Assuming a Rayleigh-type process we find fractionation constants ε of −60±15‰, 8±2‰ and 1±1‰, for δ 15 N, δ 18 O and 17 O, respectively. A photolysis model yields an upper limit for the photolytic fractionation constant 15 ε of δ 15 N, consistent with lab and field measurements, and demonstrates a high sensitivity of 15 ε to the incident actinic flux spectrum. The photolytic 15 ε is process-specific and therefore applies to any snow covered location. Previously published 15 ε values are not representative for conditions at the Earth surface, but apply only to the UV lamp used in the reported experiment (Blunier et al., 2005;Jacobi et al., 2006). Depletion of oxygen stable isotopes is attributed to photolysis followed by isotopic exchange with water and hydroxyl radicals. Conversely, 15 N enrichment of the NO

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“…No REMPI signals were detected just after deposition of HNO 3 since the dissolution and ionization of HNO 3 into H + and NO 3 -on the PCI film surface is a slow process, on the order of 10 min. 18 The measured evolution curve in Figure 2 can be fitted to a single-exponential curve with a rate constant of (5.3 ( 0.2) × 10 -3 s -1 . During the intercept of this measurement, the photodissociation laser pulse at 305 nm was blocked.…”

Section: Simulation Of Time-of-flight Spectra Of O Atomsmentioning

confidence: 99%

Release of Oxygen Atoms and Nitric Oxide Molecules from the Ultraviolet Photodissociation of Nitrate Adsorbed on Water Ice Films at 100 K

Yabushita¹,

Kawanaka²,

Kawasaki³

et al. 2007

J. Phys. Chem. A

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Production of O((3)P(J), J = 2, 1, 0) atoms from the 295-320 nm photodissociation of NO(3)- adsorbed on water polycrystalline ice films at 100 K was directly confirmed using the resonance-enhanced multiphoton ionization technique. Detection of the O atom signals required an induction period after deposition of HNO3 onto the ice film held at 130 K due to the slow ionization rate of HNO(3) to H+ and NO(3)- with a rate constant of k = (5.3 +/- 0.2) x 10(-3)s(-1). Translational energy distributions of the O atoms were represented by a combination of two Maxwell-Boltzmann energy distributions with translational temperatures of 2000 and 100 K. Direct detection of NO from the secondary photodissociation process was also successful. On the atmospheric implications, the influence of the direct release of the oxygen atoms into the air from NO(3)- adsorbed on the natural snowpack was included in an atmospheric model calculation on the mixing ratios of ozone and nitric oxide at the South Pole, and the results compared favorably with the field data.

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Ionization of Nitric Acid on Ice

Cited by 22 publications

References 26 publications

Photolytic control of the nitrate stable isotope signal in snow and atmosphere of East Antarctica and implications for reactive nitrogen cycling

Photolytic control of the nitrate stable isotope signal in snow and atmosphere of East Antarctica and implications for reactive nitrogen cycling

Photolysis imprint in the nitrate stable isotope signal in snow and atmosphere of East Antarctica and implications for reactive nitrogen cycling

Release of Oxygen Atoms and Nitric Oxide Molecules from the Ultraviolet Photodissociation of Nitrate Adsorbed on Water Ice Films at 100 K

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