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1. Reaction Acceleration Promoted by Partial Solvation at the Gas/Solution Interface

   https://doi.org/10.1002/cplu.202100373  

   Qiu, Lingqi; Wei, Zhenwei; Nie, Honggang; Cooks, R_Graham (September 2021, ChemPlusChem)

   Abstract The kinetics of organic reactions of different types in microvolumes (droplets, thin films, and sealed tubes) show effects of gas/solution interfacial area, reaction molecularity and solvent polarity. Partial solvation at the gas/solution interface is a major contributor to the 10⁴‐fold reaction acceleration seen in bimolecular but not unimolecular reactions in microdroplets. Reaction acceleration can be used to manipulate selectivity by solvent choice. 

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2. Accelerated reactions of amines with carbon dioxide driven by superacid at the microdroplet interface

   https://doi.org/10.1039/d0sc05625a  

   Huang, Kai-Hung; Wei, Zhenwei; Cooks, R. Graham (February 2021, Chemical Science)

   null (Ed.)

   Microdroplets display distinctive interfacial chemistry, manifested as accelerated reactions relative to those observed for the same reagents in bulk. Carbon dioxide undergoes C–N bond formation reactions with amines at the interface of droplets to form carbamic acids. Electrospray ionization mass spectrometry displays the reaction products in the form of the protonated and deprotonated carbamic acid. Electrosonic spray ionization (ESSI) utilizing carbon dioxide as nebulization gas, confines reaction to the gas–liquid interface where it proceeds much faster than in the bulk. Intriguingly, trace amounts of water accelerate the reaction, presumably by formation of superacid or superbase at the water interface. The suggested mechanism of protonation of CO 2 followed by nucleophilic attack by the amine is analogous to that previously advanced for imidazole formation from carboxylic acids and diamines. 

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3. Radical surface chemistry: Augmentation of reactivity by radicals at aqueous interfaces

   https://doi.org/10.1016/j.surfrep.2025.100668  

   Kolasinski, Kurt W (November 2025, Surface Science Reports)

   Cooperativity and non-additive interactions play central roles in the unusual and surprising behavior of water. A host of reactive oxygen species (ROS) including the hydroxyl radical •OH, superoxide radical anion (O2–•), hydroperoxide radical (HO2•), singlet oxygen (1O2), and also the more recently discussed water radical cation/anion pair (H2O+•/H2O–•) all add to the more familiar acid/base chemical pathways tread by hydronium (H3O+) and hydroxide (OH–). This is amplified in surface science because interfacial water – whether found at the gas/liquid, gas/solid, or liquid/solid interface – poses yet more unique behavior. This review explores the unexpected chemistry associated with ambient temperature aqueous interfaces much of which is mediated not only by ions and neutrals as expected, but also radical species. Water microdroplets catalyze numerous reactions and can also support simultaneous oxidation and reduction reactions through the production of reactive intermediates that owe their existence to the unique influence of the air/water or oil/water interface. Interfacial water influences and is influenced by the ubiquitous phenomenon of contact electrification, a manifestation of spontaneous symmetry breaking. The mechanisms of chemistry not only on and in microdroplets but also at the gas/solid and liquid/solid interfaces rely on a broad set of chemical transformations mediated by radicals. Furthermore, because aqueous macro- and micro-interfaces are ubiquitous on Earth, we find that water radical-mediated chemistry has applications to atmospheric chemistry, geochemistry, mineral weathering, pre-biotic chemistry, enhanced enzyme performance, wastewater remediation, public health, mechanochemistry, and potentially novel routes to pharmaceuticals. 

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4. Plasma-droplet interaction study to assess transport limitations and the role of ^⋅ OH, O ^⋅ ,H ^⋅ ,O ₂ (a ¹ Δ _g ),O ₃ , He(2 ³ S) and Ar(1s ₅ ) in formate decomposition

   https://doi.org/10.1088/1361-6595/ac2676  

   Nayak, Gaurav; Oinuma, Gaku; Yue, Yuanfu; Santos Sousa, João; Bruggeman, Peter J (November 2021, Plasma Sources Science and Technology)

   Abstract Plasmas interacting with liquid microdroplets are gaining momentum due to their ability to significantly enhance the reactivity transfer from the gas phase plasma to the liquid. This is, for example, critically important for efficiently decomposing organic pollutants in water. In this contribution, the role of ⋅ OH as well as non- ⋅ OH-driven chemistry initiated by the activation of small water microdroplets in a controlled environment by diffuse RF glow discharge in He with different gas admixtures (Ar, O 2 and humidified He) at atmospheric pressure is quantified. The effect of short-lived radicals such as O ⋅ and H ⋅ atoms, singlet delta oxygen (O 2 ( a 1 Δ g )), O 3 and metastable atoms of He and Ar, besides ⋅ OH radicals, on the decomposition of formate dissolved in droplets was analyzed using detailed plasma diagnostics, droplet characterization and ex situ chemical analysis of the treated droplets. The formate decomposition increased with increasing droplet residence time in the plasma, with ∼70% decomposition occurring within ∼15 ms of the plasma treatment time. The formate oxidation in the droplets is shown to be limited by the gas phase ⋅ OH flux at lower H 2 O concentrations with a significant enhancement in the formate decomposition at the lowest water concentration, attributed to e − /ion-induced reactions. However, the oxidation is diffusion limited in the liquid phase at higher gaseous ⋅ OH concentrations. The formate decomposition in He/O 2 plasma was similar, although with an order of magnitude higher O ⋅ radical density than the ⋅ OH density in the corresponding He/H 2 O plasma. Using a one-dimensional reaction–diffusion model, we showed that O 2 ( a 1 Δ g ) and O 3 did not play a significant role and the decomposition was due to O ⋅ , and possibly ⋅ OH generated in the vapor containing droplet-plasma boundary layer. 

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5. The role of analyte concentration in accelerated reaction rates in evaporating droplets

   https://doi.org/10.1039/d3sc00259d  

   Chen, Casey J.; Williams, Evan R. (May 2023, Chemical Science)

   Accelerated reactions in microdroplets have been reported for a wide range of reactions with some microdroplet reactions occurring over a million times faster than the same reaction in bulk solution. Unique chemistry at the air–water interface has been implicated as a primary factor for accelerated reaction rates, but the role of analyte concentration in evaporating droplets has not been as well studied. Here, theta-glass electrospray emitters and mass spectrometry are used to rapidly mix two solutions on the low to sub-microsecond time scale and produce aqueous nanodrops with different sizes and lifetimes. We demonstrate that for a simple bimolecular reaction where surface chemistry does not appear to play a role, reaction rate acceleration factors are between 10 2 and 10 7 for different initial solution concentrations, and these values do not depend on nanodrop size. A rate acceleration factor of 10 7 is among the highest reported and can be attributed to concentration of analyte molecules, initially far apart in dilute solution, but brought into close proximity in the nanodrop through evaporation of solvent from the nanodrops prior to ion formation. These data indicate that analyte concentration phenomenon is a significant factor in reaction acceleration where droplet volume throughout the experiment is not carefully controlled. 

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