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1. Structure of the aqueous electron

   https://doi.org/10.1039/C9CP04222A  

   Herbert, John M. (September 2019, Physical Chemistry Chemical Physics)

   null (Ed.)

   Recently there has been a revival of interest in the basic structure of the aqueous or “hydrated” electron, e − (aq). According to the conventional picture, this species occupies a cavity or excluded volume in the structure of liquid water, with a characteristic absorption spectrum ascribable to s → p excitations of a particle in a quasi-spherical box. This traditional picture has been questioned over the past few years, however, on the basis of a one-electron pseudopotential model that predicts a more delocalized spin density and no distinct cavity. This Perspective reviews the known experimental properties of e − (aq) along with attempts to reproduce and understand them using both one-electron models and many-electron quantum chemistry calculations. The overwhelming weight of the evidence continues to support the conventional excluded-volume picture of the aqueous electron. 

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2. Interaction Energy Analysis of Monovalent Inorganic Anions in Bulk Water Versus Air/Water Interface

   https://doi.org/10.3390/molecules26216719  

   Herbert, John M.; Paul, Suranjan K. (November 2021, Molecules)

   Soft anions exhibit surface activity at the air/water interface that can be probed using surface-sensitive vibrational spectroscopy, but the structural implications of this surface activity remain a matter of debate. Here, we examine the nature of anion–water interactions at the air/water interface using a combination of molecular dynamics simulations and quantum-mechanical energy decomposition analysis based on symmetry-adapted perturbation theory. Results are presented for a set of monovalent anions, including Cl−, Br−, I−, CN−, OCN−, SCN−, NO2−, NO3−, and ClOn− (n=1,2,3,4), several of which are archetypal examples of surface-active species. In all cases, we find that average anion–water interaction energies are systematically larger in bulk water although the difference (with respect to the same quantity computed in the interfacial environment) is well within the magnitude of the instantaneous fluctuations. Specifically for the surface-active species Br−(aq), I−(aq), ClO4−(aq), and SCN−(aq), and also for ClO−(aq), the charge-transfer (CT) energy is found to be larger at the interface than it is in bulk water, by an amount that is greater than the standard deviation of the fluctuations. The Cl−(aq) ion has a slightly larger CT energy at the interface, but NO3−(aq) does not; these two species are borderline cases where consensus is lacking regarding their surface activity. However, CT stabilization amounts to <20% of the total induction energy for each of the ions considered here, and CT-free polarization energies are systematically larger in bulk water in all cases. As such, the role of these effects in the surface activity of soft anions remains unclear. This analysis complements our recent work suggesting that the short-range solvation structure around these ions is scarcely different at the air/water interface from what it is in bulk water. Together, these observations suggest that changes in first-shell hydration structure around soft anions cannot explain observed surface activities. 

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3. HCOO ⁻ _aq degradation in droplets by OH _aq in an atmospheric pressure glow discharge

   https://doi.org/10.1088/1361-6463/acc958  

   Meyer, Mackenzie; Nayak, Gaurav; Bruggeman, Peter J.; Kushner, Mark J. (April 2023, Journal of Physics D: Applied Physics)

   Abstract Plasmas in contact with liquids can degrade organic molecules in a solution, as reactive oxygen and nitrogen species produced in the plasma solvate into the liquid. Immersing small droplets (tens of microns in diameter) in the plasma can more rapidly activate the liquid compared to treating a large volume of liquid with a smaller surface-to-volume ratio. The interactions between a radio frequency glow discharge sustained in He/H₂O and a water droplet containing formate (HCOO⁻_aq) immersed in and flowing through the plasma were modeled using a zero-dimensional global plasma chemistry model to investigate these activation processes. HCOO⁻_aqinteracts with OH_aq, which is produced from the solvation of OH from the gas phase. The resulting HCOO⁻_aqconcentrations were benchmarked with previously reported experimental measurements. The diameter of the droplet, initial HCOO⁻_aqconcentration, and gas flow rate affect only the HCOO⁻_aqconcentration and OH_aqdensity, leaving the OH density in the gas phase unaffected. Power deposition and gas mixture (e.g. percentage of H₂O) change both the gas and liquid phase chemistry. A general trend was observed: during the first portion of droplet exposure to the plasma, OH_aqprimarily consumes HCOO⁻_aq. However, O₂⁻_aq, a byproduct of HCOO⁻_aqconsumption, consumes OH_aqonce O₂⁻_aqreaches a critically large density. Using HCOO⁻_aqas a surrogate for OH_aq-sensitive contaminants, combinations of residence time, droplet diameter, water vapor density, and power will determine the optimum remediation strategy. 

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4. Ab initio metadynamics calculations of dimethylamine for probing p K _b variations in bulk vs. surface environments

   https://doi.org/10.1039/D0CP03832F  

   Biswas, Sohag; Kwon, Hyuna; Barsanti, Kelley C.; Myllys, Nanna; Smith, James N.; Wong, Bryan M. (November 2020, Physical Chemistry Chemical Physics)

   null (Ed.)

   The basicity constant, or p K b , is an intrinsic physical property of bases that gives a measure of its proton affinity in macroscopic environments. While the p K b is typically defined in reference to the bulk aqueous phase, several studies have suggested that this value can differ significantly at the air–water interface (which can have significant ramifications for particle surface chemistry and aerosol growth modeling). To provide mechanistic insight into surface proton affinity, we carried out ab initio metadynamics calculations to (1) explore the free-energy profile of dimethylamine and (2) provide reasonable estimates of the p K b value in different solvent environments. We find that the free-energy profiles obtained with our metadynamics calculations show a dramatic variation, with interfacial aqueous dimethylamine p K b values being significantly lower than in the bulk aqueous environment. Furthermore, our metadynamics calculations indicate that these variations are due to reduced hydrogen bonding at the air–water surface. Taken together, our quantum mechanical metadynamics calculations show that the reactivity of dimethylamine is surprisingly complex, leading to p K b variations that critically depend on the different atomic interactions occurring at the microscopic molecular level. 

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5. Electronic Excitation and High‐Energy Reactions Originate From Anionic Microdroplets Formed by Electrospray or Pneumatic Nebulization

   https://doi.org/10.1002/anie.202424662  

   Chen, Casey_J; Avadhani, Veena_S; Williams, Evan_R (March 2025, Angewandte Chemie International Edition)

   Abstract Formation of energetic species at the surface of aqueous microdroplets, including abundant hydroxyl radicals, oxidation products, and ionized N₂and O₂gas, has been previously attributed to the high electric field at the droplet surface. Here, evidence for a new mechanism for electronic excitation involving electron emission from negatively charged water droplets is shown. Droplet evaporation can lead to the emission of ions and droplet fission, but unlike positively charged droplets, negatively charged droplets can also shed charge by electron emission. With nanoelectrospray, no anions or negatively charged droplets are produced with a positive electrospray potential. In contrast, abundant O₂^+•and H₃O⁺(H₂O) are formed with negative electrospray. When toluene vapor is introduced with negative electrospray, abundant toluene radical cations and fragments are produced. Both O₂^+•and toluene radical cations are produced with pneumatic nebulization. The electrons produced from evaporating negatively charged droplets can be accelerated by an external electric field in electrospray, or by the field generated between droplets with opposite polarities produced by pneumatic nebulization. This electron emission/ionization mechanism leads to electronic excitation >10 eV, and it may explain some of the surprising chemistries that were previously attributed to the high intrinsic electric field at the surface of aqueous droplets. 

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