Infrared spectrum of NH4+(H2O): Evidence for mode specific fragmentation

Pankewitz, Tobias; Lagutschenkov, Anita; Niedner‐Schatteburg, Gereon; Xantheas, Sotiris S.; Lee, Yuan-Tseh

doi:10.1063/1.2435352

Cited by 67 publications

(76 citation statements)

References 103 publications

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“…The two types of experiments, with and without messenger-tagging, can lead to substantially different IR spectra, typically with certain IR-active modes missing from the IRMPD spectrum. 25,31,32 We find here that comparison of the IRMPD spectra to the corresponding single-photon IRPD spectra aids in identifying the mechanism for these missing peaks.…”

Section: Introductionmentioning

confidence: 90%

“…A mechanism involving (i) has been explored in the OH stretch region by Pankewitz et al 32 for the NH 4 + (H 2 O) cation and used to analyze a slew of previous experimental results on singly hydrated cationic systems. When the cluster dissociation energy is high, the IRMPD spectra show unexpectedly low peak intensities for the antisymmetric water OH stretch compared to those for the symmetric stretch.…”

Section: Analysis and Discussionmentioning

confidence: 99%

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Vibrational Spectroscopy of Bisulfate/Sulfuric Acid/Water Clusters: Structure, Stability, and Infrared Multiple-Photon Dissociation Intensities

et al. 2013

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ABSTRACT:The structure and stability of mass-selected bisulfate, sulfuric acid, and water cluster anions, HSO 4 − (H 2 SO 4 ) m (H 2 O) n , are studied by infrared photodissociation spectroscopy aided by electronic structure calculations. The triply hydrogen-bound HSO 4 − (H 2 SO 4 ) configuration appears as a recurring motif in the bare clusters, while incorporation of water disrupts this stable motif for clusters with m > 1. Infrared-active vibrations predominantly involving distortions of the hydrogenbound network are notably missing from the infrared multiplephoton dissociation (IRMPD) spectra of these ions but are fully recovered by messenger-tagging the clusters with H 2 . A simple model is used to explain the observed "IRMPD transparency".

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Section: Introductionmentioning

confidence: 90%

Section: Analysis and Discussionmentioning

confidence: 99%

Vibrational Spectroscopy of Bisulfate/Sulfuric Acid/Water Clusters: Structure, Stability, and Infrared Multiple-Photon Dissociation Intensities

et al. 2013

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“…One strategy to gain a detailed understanding of how ions and water molecules interact is to build up a solution, one molecule of water at a time. [1] Vibrational spectroscopy is a powerful structural tool for investigating hydrated ions, and has been used to investigate the structures of hydrated monovalent cations, including Ag + , [2] H + , [3][4][5][6] Cs + , [7,8] Cu + , [2] K + , [9] Mg + , [10] NH 4 + , [11,12] and Ni + , [13] and hydrated anions, including Cl À , [14,15] e À , [16] F À , [15,17] HO À , [18] and SO 4 2À . [19] Despite serving critical regulatory and structural roles in biology, experimental studies of hydrated, multiply charged ions have lagged behind those of singly charged ions, owing to the great difficulty in producing them in significant abundances; for example, formation of doubly hydrated, divalent calcium by condensation results in rapid dissociation aided by Coulomb repulsion [Eq.…”

Section: Introductionmentioning

confidence: 99%

“…[11] Niedner-Schatteburg and co-workers proposed that weak intramolecular vibrational relaxation (IVR) coupling for u asym reduces the photodissociation efficiency for this mode for NH 4 + A C H T U N G T R E N N U N G (H 2 O). [11] Although many of the effects of slow IVR should be significantly reduced in these experiments as a result of the 100 ms time period between laser pulses and the presence of multiple water molecules, radiative emission from u asym should be fast and this may be a competitive relaxation mechanism. [49] Alternatively, the absorption of multiple photons is more important for the smaller clusters because of higher dissociation energies for the loss of a water molecule.…”

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confidence: 99%

Hydration of the Calcium Dication: Direct Evidence for Second Shell Formation from Infrared Spectroscopy

2007

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Infrared laser action spectroscopy in a Fourier-transform ion cyclotron resonance mass spectrometer is used in conjunction with ab initio calculations to investigate doubly charged, hydrated clusters of calcium formed by electrospray ionization. Six water molecules coordinate directly to the calcium dication, whereas the seventh water molecule is incorporated into a second solvation shell. Spectral features indicate the presence of multiple structures of Ca(H2O)(7)2+ in which outer-shell water molecules accept either one (single acceptor) or two (double acceptor) hydrogen bonds from inner-shell water molecules. Double-acceptor water molecules are predominantly observed in the second solvent shells of clusters containing eight or nine water molecules. Increased hydration results in spectroscopic signatures consistent with additional second-shell water molecules, particularly the appearance of inner-shell water molecules that donate two hydrogen bonds (double donor) to the second solvent shell. This is the first reported use of infrared spectroscopy to investigate shell structure of a hydrated multiply charged cation in the gas phase and illustrates the effectiveness of this method to probe the structures of hydrated ions.

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“…145,146 Elegant experiments made it possible to follow the evolution of vibrational spectra and of reactivity with cluster size, allowing for molecular level descriptions of hydrated clusters. [147][148][149][150] Important and general messages emerged from these studies about the role of the hydration structure around the ionic core in determining spectroscopic and chemical properties of these species. 151 Computational studies predict red shifts in the vibrational spectra of hydrates and emphasize the importance and necessity for anharmonic effects to be treated appropriately to describe their properties.…”

Section: Cluster Models For Condensed Phases Aerosols and Interfacesmentioning

confidence: 99%

Perspective: Water cluster mediated atmospheric chemistry

Vaida

2011

The Journal of Chemical Physics

269

249

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The importance of water in atmospheric and environmental chemistry initiated recent studies with results documenting catalysis, suppression and anti-catalysis of thermal and photochemical reactions due to hydrogen bonding of reagents with water. Water, even one water molecule in binary complexes, has been shown by quantum chemistry to stabilize the transition state and lower its energy. However, new results underscore the need to evaluate the relative competing rates between reaction and dissipation to elucidate the role of water in chemistry. Water clusters have been used successfully as models for reactions in gas-phase, in aqueous condensed phases and at aqueous surfaces. Opportunities for experimental and theoretical chemical physics to make fundamental new discoveries abound. Work in this field is timely given the importance of water in atmospheric and environmental chemistry.

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Infrared spectrum of NH4+(H2O): Evidence for mode specific fragmentation

Cited by 67 publications

References 103 publications

Vibrational Spectroscopy of Bisulfate/Sulfuric Acid/Water Clusters: Structure, Stability, and Infrared Multiple-Photon Dissociation Intensities

Vibrational Spectroscopy of Bisulfate/Sulfuric Acid/Water Clusters: Structure, Stability, and Infrared Multiple-Photon Dissociation Intensities

Hydration of the Calcium Dication: Direct Evidence for Second Shell Formation from Infrared Spectroscopy

Perspective: Water cluster mediated atmospheric chemistry

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