Covalent and Ionic States of Strong Acids at the Ice Surface

Devlin, J. Paul; Uras, Nevin; Rahman, Mohammed M.; Buch, V.

doi:10.1002/ijch.199900033

Cited by 25 publications

(50 citation statements)

References 44 publications

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“…This broad absorption is ubiquitous in the vibrational spectroscopy of aqueous acid solutions and is thus broadly recognized as the spectroscopic hallmark of the aqueous proton. The presence of aqueous protons suggests that most (some) HNO 3 molecules have dissociated in the 5–15% (20–60%) HNO 3 mole fraction cryogenic nitric acid solutions even at temperatures as low as 45 K, a significantly lower temperature than those of previous spectroscopic studies. ,− …”

Section: Resultsmentioning

confidence: 89%

Spectroscopic Study of HNO₃Dissociation on Ice

2012

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A detailed spectroscopic study of HNO(3):H(2)O binary amorphous mixtures, and of the adsorption of HNO(3) onto ice, is reported. Using a classical optics model, the extent of intermixing and of ionic dissociation of adsorbed HNO(3), which forms a strong acid with liquid water, is determined as a function of HNO(3) coverage and temperature. Even at temperatures as low as 45 K, where intermixing is limited to at most a few molecular layers at the interface, ionic dissociation of adsorbed HNO(3) is observed to be extensive. While some amount of molecularly adsorbed HNO(3) is observed at the surface of ice at 45 K, its ionic dissociation occurs irreversibly upon heating the ice substrate to 120 K. The molecularly adsorbed state of HNO(3) is not restored upon cooling, suggesting HNO(3) is a metastable entity at the surface of ice. Therefore, despite ionic dissociation of HNO(3) being thermodynamically favored, it appears to be kinetically inhibited at the surface of amorphous solid water at temperatures below 120 K.

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Section: Resultsmentioning

confidence: 89%

Spectroscopic Study of HNO₃Dissociation on Ice

2012

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“…Investigating the chemical state of HNO 3 at the surface of supercooled solutions or ice therefore requires surface-sensitive spectroscopic tools and/or appropriate sample preparation methods. Only by reaching cryogenic temperatures (i.e., in the 70−135 K range by Devlin et al 14 and the 130−150 K range by Pursell et al 13 ) has molecular nitric acid been observed at the surface of ice. Unfortunately, both studies relied on FTIR spectroscopy, which lacks the surface specificity and sensitivity to detect submonolayer coverages of HNO 3 adsorbed onto ice.…”

mentioning

confidence: 99%

“…Accordingly, their sample preparation methodology and their experimental conditions suggest that they observed molecular nitric acid as a result of multilayer condensation 13 or in the form of nitric acid nanocrystals at the surface of ice. 14 Recently, Krepelova et al 35 used near-edge X-ray absorption fine structure (NEXAFS) to study the adsorption of HNO 3 onto ice at 230 K, relying, however, on heterogeneous NO 2 hydrolysis as a source of HNO 3 . They reported the observation of nitrates dissolved within a 1.1 nm thick supercooled nitric acid solution layer at the ice surface, but they could not observe molecular HNO 3 under these conditions.…”

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confidence: 99%

“…Given its major role in a plethora of environmental processes, the dissociative adsorption and acid–base chemistry of HNO 3 at aqueous interfaces continues to attract tremendous interest from both theoretical − and experimental perspectives. − Indeed, our understanding of several important atmospheric chemistry processes hinges on a quantitative description of the factors and parameters that control whether HNO 3 exists in its molecular or its dissociated form at the surface of atmospheric aerosols and of ice. For instance, this would impact our interpretation of the formation, stability, and reactivity of nitrates in urban particulate matter, − the atmospheric reactive nitrogen budget, − the intriguing NO x photochemical fluxes from snowpacks, ,, and the formation and lifetime of cirrus clouds. − …”

mentioning

confidence: 99%

“…Unfortunately, both studies relied on FTIR spectroscopy, which lacks the surface specificity and sensitivity to detect submonolayer coverages of HNO 3 adsorbed onto ice. Accordingly, their sample preparation methodology and their experimental conditions suggest that they observed molecular nitric acid as a result of multilayer condensation or in the form of nitric acid nanocrystals at the surface of ice . Recently, Krepelova et al used near-edge X-ray absorption fine structure (NEXAFS) to study the adsorption of HNO 3 onto ice at 230 K, relying, however, on heterogeneous NO 2 hydrolysis as a source of HNO 3 .…”

mentioning

confidence: 99%

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Dissociative Adsorption of Nitric Acid at the Surface of Amorphous Solid Water Revealed by X-ray Absorption Spectroscopy

Marcotte

Ayotte

Bendounan

et al. 2013

J. Phys. Chem. Lett.

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A spectral feature unique to the molecularly adsorbed state of HNO 3 is found in X-ray absorption spectroscopy. This distinctive signature reveals the extent to which nitric acid is ionically dissociated upon its adsorption on amorphous solid water (ASW) at low coverage and low temperature. Thermal annealing induces irreversible proton transfer from HNO 3(ads) , demonstrating that it is metastable with respect to ionic dissociation below 100 K at the surface of ASW. The slight decrease in ionic dissociation propensity reported for nitric acid at liquid water surfaces thus appears to be overwhelmed by the strong exothermicity of this reaction as its entropic inhibition becomes increasingly suppressed the lower the temperature. These findings may be relevant for atmospheric chemistry processes involving nitric acid, which should thus, according to thermodynamic considerations, be expected to behave as a strong acid at the surface of supercooled aerosols and of the quasi-liquid layer.

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