When Liquid Rays Become Gas Rays: Can Evaporation Ever Be Non-Maxwellian?

Nathanson, Gilbert M.

doi:10.1007/978-3-030-63963-1_27

Cited by 2 publications

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“…Our group has used microjets of pure and salty water and hydrocarbon fuels to explore collisions of inert and reactive gases using velocity-resolved mass spectrometry . Examples of our nonreactive studies include the startling super-Maxwellian evaporation of helium from aqueous , and hydrocarbon liquids and the ability of organic molecules with acidic or basic functional groups (carboxylic acids and amines) to dissolve into water on almost every collision . This Account focuses on the lessons that we are learning in carrying out gas–microjet reactive scattering.…”

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confidence: 99%

Exploring Gas–Liquid Reactions with Microjets: Lessons We Are Learning

Gao

Nathanson

2022

Acc. Chem. Res.

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Conspectus Liquid water is all around us: at the beach, in a cloud, from a faucet, inside a spray tower, covering our lungs. It is fascinating to imagine what happens to a reactive gas molecule as it approaches the surface of water in these examples. Some incoming molecules may first be deflected away after colliding with an evaporating water molecule. Those that do strike surface H2O or other surface species may bounce directly off or become momentarily trapped through hydrogen bonding or other attractive forces. The adsorbed gas molecule can then desorb immediately or instead dissolve, passing through the interfacial region and into the bulk, perhaps diffusing back to the surface and evaporating before reacting. Alternatively, it may react with solute or water molecules in the interfacial or bulk regions, and a reaction intermediate or the final product may then desorb into the gas phase. Building a “blow by blow” picture of these pathways is challenging for vacuum-based techniques because of the high vapor pressure of water. In particular, collisions within the thick vapor cloud created by evaporating molecules just above the surface scramble the trajectories and internal states of the gaseous target molecules, hindering construction of gas–liquid reaction mechanisms at the atomic scale that we strive to map out. The introduction of the microjet in 1988 by Faubel, Schlemmer, and Toennies opened up entirely new possibilities. Their inspired solution seems so simple: narrow the end of a glass tube to a diameter smaller than the mean free path of the vapor molecules and then push the liquid through the tube at speeds of a car on a highway. The narrow liquid stream creates a sparse vapor cloud, with water molecules spaced far enough apart that they and the reactant gases interact, at most, weakly. Experimentalists, however, confront a host of challenges: nozzle clogging, unstable jetting, searching for vacuum-compatible solutions, measuring low signal levels, and teasing out artifacts because the slender jet is the smallest surface in the vacuum chamber. In this Account, we describe lessons that we are learning as we explore gases (DCl, (HCOOH)2, N2O5) reacting with water molecules and solute ions in the near-interfacial region of these fast-flowing aqueous microjets.

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