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1. 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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2. Spontaneous Water Radical Cation Oxidation at Double Bonds in Microdroplets

   https://doi.org/10.3389/fchem.2022.903774  

   Qiu, Lingqi; Morato, Nicolás M.; Huang, Kai-Hung; Cooks, R. Graham (April 2022, Frontiers in Chemistry)

   Spontaneous oxidation of compounds containing diverse X=Y moieties (e.g., sulfonamides, ketones, esters, sulfones) occurs readily in organic-solvent microdroplets. This surprising phenomenon is proposed to be driven by the generation of an intermediate species [M+H 2 O] +· : a covalent adduct of water radical cation (H 2 O +· ) with the reactant molecule (M). The adduct is observed in the positive ion mass spectrum while its formation in the interfacial region of the microdroplet (i.e., at the air-droplet interface) is indicated by the strong dependence of the oxidation product formation on the spray distance (which reflects the droplet size and consequently the surface-to-volume ratio) and the solvent composition. Importantly, based on the screening of a ca. 21,000-compound library and the detailed consideration of six functional groups, the formation of a molecular adduct with the water radical cation is a significant route to ionization in positive ion mode electrospray, where it is favored in those compounds with X=Y moieties which lack basic groups. A set of model monofunctional systems was studied and in one case, benzyl benzoate, evidence was found for oxidation driven by hydroxyl radical adduct formation followed by protonation in addition to the dominant water radical cation addition process. Significant implications of molecular ionization by water radical cations for oxidation processes in atmospheric aerosols, analytical mass spectrometry and small-scale synthesis are noted. 

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3. Accelerated microdroplet synthesis of benzimidazoles by nucleophilic addition to protonated carboxylic acids

   https://doi.org/10.1039/d0sc02467h  

   Basuri, Pallab; Gonzalez, L. Edwin; Morato, Nicolás M.; Pradeep, Thalappil; Cooks, R. Graham (December 2020, Chemical Science)

   null (Ed.)

   We report a metal-free novel route for the accelerated synthesis of benzimidazole and its derivatives in the ambient atmosphere. The synthetic procedure involves 1,2-aromatic diamines and alkyl or aryl carboxylic acids reacting in electrostatically charged microdroplets generated using a nano-electrospray (nESI) ion source. The reactions are accelerated by orders of magnitude in comparison to the bulk. No other acid, base or catalyst is used. Online analysis of the microdroplet accelerated reaction products is performed by mass spectrometry. We provide evidence for an acid catalyzed reaction mechanism based on identification of the intermediate arylamides. Their dehydration to give benzimidazoles occurs in a subsequent thermally enhanced step. It is suggested that the extraordinary acidity at the droplet surface allows the carboxylic acid to function as a C-centered electrophile. Comparisons of this methodology with data from thin film and bulk synthesis lead to the proposal of three key steps in the reaction: (i) formation of an unusual reagent (protonated carboxylic acid) because of the extraordinary conditions at the droplet interface, (ii) accelerated bimolecular reaction because of limited solvation at the interface and (iii) thermally assisted elimination of water. Eleven examples are shown as evidence of the scope of this chemistry. The accelerated synthesis has been scaled-up to establish the substituent-dependence and to isolate products for NMR characterization. 

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4. Simultaneous and Spontaneous Oxidation and Reduction in Microdroplets by the Water Radical Cation/Anion Pair

   https://doi.org/10.1002/anie.202210765  

   Qiu, Lingqi; Cooks, R. Graham (September 2022, Angewandte Chemie International Edition)

   Abstract Microdroplets show unique chemistry, especially in their intrinsic redox properties, and to this we here add a case of simultaneous and spontaneous oxidation and reduction. We report the concurrent conversions of several phosphonates to phosphonic acids by reduction (R−P → H−P) and to pentavalent phosphoric acids by oxidation. The experimental results suggest that the active reagent is the water radical cation/anion pair. The water radical cation is observed directly as the ionized water dimer while the water radical anion is only seen indirectly though the spontaneous reduction of carbon dioxide to formate. The coexistence of oxidative and reductive species in turn supports the proposal of a double‐layer structure at the microdroplet surface, where the water radical cation and radical anion are separated and accumulated. 

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5. Catalytic Activity of Water-Soluble Palladium Nanoparticles with Anionic and Cationic Capping Ligands for Reduction, Oxidation, and C-C Coupling Reactions in Water

   https://doi.org/10.3390/nano15050405  

   Farag, Jan W; Khalil, Ragaa; Avila, Edwin; Shon, Young-Seok (March 2025, Nanomaterials)

   The availability of water-soluble nanoparticles allows catalytic reactions to occur in highly desirable green environments. The catalytic activity and selectivity of water-soluble palladium nanoparticles capped with 6-(carboxylate)hexanethiolate (C6-PdNP) and 5-(trimethylammonio)pentanethiolate (C5-PdNP) were investigated for the reduction of 4-nitrophenol, the oxidation of α,β-conjugated aldehydes, and the C-C coupling of phenylboronic acid. The study showed that between the two PdNPs, C6-PdNP exhibits better catalytic activity for the reduction of 4-nitrophenol to 4-aminophenol in the presence of sodium borohydride and the selective oxidation of conjugated aldehydes to conjugated carboxylic acids. For the latter reaction, molecular hydrogen (H2) and H2O act as oxidants for the surface palladium atoms on PdNPs and conjugated aldehyde substrates, respectively. The results indicated that the competing addition activities of Pd-H and H2O toward the π-bond of different unsaturated substrates promote either reduction or oxidation reactions under mild conditions in organic solvent-free environments. In comparison, C5-PdNP exhibited higher catalytic activity for the C-C coupling of phenylboronic acid. Gas chromatography–mass spectrometry (GC-MS) was mainly used as an analytical technique to examine the products of catalytic reactions. 

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