Your search keyword '"McCoy AB"' showing total 8 results

1. Deconstructing water's diffuse OH stretching vibrational spectrum with cold clusters.

Author

Yang N, Duong CH, Kelleher PJ, McCoy AB, and Johnson MA

Abstract

The diffuse vibrational envelope displayed by water precludes direct observation of how different hydrogen-bond topologies dictate the spectral response of individual hydroxy group (OH) oscillators. Using cold, isotopically labeled cluster ions, we report the spectral signatures of a single, intact water (H 2 O) molecule embedded at various sites in the clathrate-like cage structure adopted by the Cs + ·(D 2 O) 20 ion. These patterns reveal the site-dependent correlation between the frequencies of the two OH groups on the same water molecule and establish that the bound OH companion of the free OH group exclusively accounts for bands in the lower-energy region of the spectrum. The observed multiplet structures reveal the homogeneous linewidths of the fundamentals and quantify the anharmonic contributions arising from coupling to both the intramolecular bending and intermolecular soft modes., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2019

2. Spectroscopic snapshots of the proton-transfer mechanism in water.

Author

Wolke CT, Fournier JA, Dzugan LC, Fagiani MR, Odbadrakh TT, Knorke H, Jordan KD, McCoy AB, Asmis KR, and Johnson MA

Abstract

The Grotthuss mechanism explains the anomalously high proton mobility in water as a sequence of proton transfers along a hydrogen-bonded (H-bonded) network. However, the vibrational spectroscopic signatures of this process are masked by the diffuse nature of the key bands in bulk water. Here we report how the much simpler vibrational spectra of cold, composition-selected heavy water clusters, D + (D 2 O) n , can be exploited to capture clear markers that encode the collective reaction coordinate along the proton-transfer event. By complexing the solvated hydronium "Eigen" cluster [D 3 O + (D 2 O) 3 ] with increasingly strong H-bond acceptor molecules (D 2 , N 2 , CO, and D 2 O), we are able to track the frequency of every O-D stretch vibration in the complex as the transferring hydron is incrementally pulled from the central hydronium to a neighboring water molecule., (Copyright © 2016, American Association for the Advancement of Science.)

Published

2016

3. Infrared-driven unimolecular reaction of CH₃CHOO Criegee intermediates to OH radical products.

Author

Liu F, Beames JM, Petit AS, McCoy AB, and Lester MI

Abstract

Ozonolysis of alkenes, an important nonphotolytic source of hydroxyl (OH) radicals in the troposphere, proceeds through energized Criegee intermediates that undergo unimolecular decay to produce OH radicals. Here, we used infrared (IR) activation of cold CH3CHOO Criegee intermediates to drive hydrogen transfer from the methyl group to the terminal oxygen, followed by dissociation to OH radicals. State-selective excitation of CH3CHOO in the CH stretch overtone region combined with sensitive OH detection revealed the IR spectrum of CH3CHOO, effective barrier height for the critical hydrogen transfer step, and rapid decay dynamics to OH products. Complementary theory provides insights on the IR overtone spectrum, as well as vibrational excitations, structural changes, and energy required to move from the minimum-energy configuration of CH3CHOO to the transition state for the hydrogen transfer reaction., (Copyright © 2014, American Association for the Advancement of Science.)

Published

2014

4. Determination of noncovalent docking by infrared spectroscopy of cold gas-phase complexes.

Author

Garand E, Kamrath MZ, Jordan PA, Wolk AB, Leavitt CM, McCoy AB, Miller SJ, and Johnson MA

Subjects

Binding Sites, Catalysis, Chemical Phenomena, Freezing, Gases, Halogenation, Hydrogen Bonding, Infrared Rays, Molecular Conformation, Molecular Structure, Stereoisomerism, Biphenyl Compounds chemistry, Oligopeptides chemistry, Spectrum Analysis methods

Abstract

Multidentate, noncovalent interactions between small molecules and biopolymer fragments are central to processes ranging from drug action to selective catalysis. We present a versatile and sensitive spectroscopic probe of functional groups engaged in hydrogen bonding in such contexts. This involves measurement of the frequency changes in specific covalent bonds upon complex formation, information drawn from otherwise transient complexes that have been extracted from solution and conformationally frozen near 10 kelvin in gas-phase clusters. Resonances closely associated with individual oscillators are easily identified through site-specific isotopic labeling, as demonstrated by application of the method to an archetypal system involving a synthetic tripeptide known to bind biaryl substrates through tailored hydrogen bonding to catalyze their asymmetric bromination. With such data, calculations readily converge on the plausible operative structures in otherwise computationally prohibitive, high-dimensionality landscapes.

Published

2012

5. Rate of gas phase association of hydroxyl radical and nitrogen dioxide.

Author

Mollner AK, Valluvadasan S, Feng L, Sprague MK, Okumura M, Milligan DB, Bloss WJ, Sander SP, Martien PT, Harley RA, McCoy AB, and Carter WP

Abstract

The reaction of OH and NO(2) to form gaseous nitric acid (HONO(2)) is among the most influential in atmospheric chemistry. Despite its importance, the rate coefficient remains poorly determined under tropospheric conditions because of difficulties in making laboratory rate measurements in air at 760 torr and uncertainties about a secondary channel producing peroxynitrous acid (HOONO). We combined two sensitive laser spectroscopy techniques to measure the overall rate of both channels and the partitioning between them at 25°C and 760 torr. The result is a significantly more precise value of the rate constant for the HONO(2) formation channel, 9.2 (±0.4) × 10(-12) cm(3) molecule(-1) s(-1) (1 SD) at 760 torr of air, which lies toward the lower end of the previously established range. We demonstrate the impact of the revised value on photochemical model predictions of ozone concentrations in the Los Angeles airshed.

Published

2010

6. Solvent-mediated electron hopping: long-range charge transfer in IBr-(CO2) photodissociation.

Author

Sheps L, Miller EM, Horvath S, Thompson MA, Parson R, McCoy AB, and Lineberger WC

Abstract

Chemical bond breaking involves coupled electronic and nuclear dynamics that can take place on multiple electronic surfaces. Here we report a time-resolved experimental and theoretical investigation of nonadiabatic dynamics during photodissociation of a complex of iodine monobromide anion with carbon dioxide [IBr-(CO2)] on the second excited (A') electronic state. Previous experimental work showed that the dissociation of bare IBr- yields only I- + Br products. However, in IBr-(CO2), time-resolved photoelectron spectroscopy reveals that a subset of the dissociating molecules undergoes an electron transfer from iodine to bromine 350 femtoseconds after the initial excitation. Ab initio calculations and molecular dynamics simulations elucidate the mechanism for this charge hop and highlight the crucial role of the carbon dioxide molecule. The charge transfer between two recoiling atoms, assisted by a single solvent-like molecule, provides a notable limiting case of solvent-driven electron transfer over a distance of 7 angstroms.

Published

2010

7. How the shape of an H-bonded network controls proton-coupled water activation in HONO formation.

Author

Relph RA, Guasco TL, Elliott BM, Kamrath MZ, McCoy AB, Steele RP, Schofield DP, Jordan KD, Viggiano AA, Ferguson EE, and Johnson MA

Abstract

Many chemical reactions in atmospheric aerosols and bulk aqueous environments are influenced by the surrounding solvation shell, but the precise molecular interactions underlying such effects have rarely been elucidated. We exploited recent advances in isomer-specific cluster vibrational spectroscopy to explore the fundamental relation between the hydrogen (H)-bonding arrangement of a set of ion-solvating water molecules and the chemical activity of this ensemble. We find that the extent to which the nitrosonium ion (NO+)and water form nitrous acid (HONO) and a hydrated proton cluster in the critical trihydrate depends sensitively on the geometrical arrangement of the water molecules in the network. Theoretical analysis of these data details the role of the water network in promoting charge delocalization.

Published

2010

8. Quantum deconstruction of the infrared spectrum of CH5+.

Author

Huang X, McCoy AB, Bowman JM, Johnson LM, Savage C, Dong F, and Nesbitt DJ

Abstract

We present two quantum calculations of the infrared spectrum of protonated methane (CH5+) using full-dimensional, ab initio-based potential energy and dipole moment surfaces. The calculated spectra compare well with a low-resolution experimental spectrum except below 1000 cm(-1), where the experimental spectrum shows no absorption. The present calculations find substantial absorption features below 1000 cm(-1), in qualitative agreement with earlier classical calculations of the spectrum. The major spectral bands are analyzed in terms of the molecular motions. Of particular interest is an intense feature at 200 cm(-1), which is due to an isomerization mode that connects two equivalent minima. Very recent high-resolution jet-cooled spectra in the CH stretch region (2825 to 3050 cm(-1)) are also reported, and assignments of the band origins are made, based on the present quantum calculations.

Published

2006