Accelerated Non-Enzymatic Fatty Acid Esterification during Microdroplet Collision: A Method for Enhanced Sustainability

2022

Angewandte Chemie

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 (RÀ P ! HÀ 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.

Section: Figurementioning

confidence: 99%

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confidence: 99%

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

Qiu

2022

Angewandte Chemie

“…[ 1 , 2 ] Chemical reactions in micron‐sized droplets under ambient conditions are often orders of magnitude faster than the equivalent bulk reactions. [ 3 , 4 , 5 , 6 , 7 , 8 , 9 ] The catalyst‐like role of microdroplets makes them excellent tools for rapid chemical derivatization[ 10 , 11 ] and small‐scale synthesis. [ 3 , 12 , 13 , 14 , 15 , 16 , 17 ] The observed reaction acceleration is explained by the peculiar environment at the droplet air/solution interface, where reactants are only partially solvated[ 1 , 2 , 18 , 19 ] and which is characterized by a high electric field.…”

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confidence: 99%

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

Qiu

2022

Angew Chem Int Ed

“…Interfacial chemistry appears to play a crucial role in facilitating biomolecule transformations in aqueous environments, as has been demonstrated in biphasic systems ( 91 ), cell condensates, and subcompartments ( 98 ), as well as in microdroplets ( 12 , 13 , 21 , 29 , 42 , 51 – 53 , 99 , 100 ). The observed generation of peptides from free amino acids at the air–water interface of pure water droplets, the simplest of all prebiotic systems, suggests that settings such as atmospheric aerosols or sea spray may have provided a unique and ubiquitous environment to overcome the energetic hurdles associated with condensation and polymerization of biomolecules in water.…”

Section: Resultsmentioning

confidence: 99%

“…Of particular interest is the observation that the air–water interface of monolayers and thin films ( 28 – 31 ), inverted micelle aerosols ( 12 ), Leidenfrost droplets ( 32 – 36 ), and charged or neutral microdroplets ( 37 – 46 ) all reveal vastly different chemical kinetics compared to bulk, with rate constants increased by up to six orders of magnitude ( 47 , 48 ). This interfacial acceleration phenomenon has been reported for prebiotically relevant reactions including condensation ( 12 , 21 , 29 , 49 – 53 ), redox ( 54 , 55 ), nucleophilic addition ( 41 , 43 ), and ultraviolet-initiated photopolymerization reactions ( 56 ).…”

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confidence: 99%

Aqueous microdroplets enable abiotic synthesis and chain extension of unique peptide isomers from free amino acids

Holden

Morato

Proc. Natl. Acad. Sci. U.S.A.

2022

Amide bond formation, the essential condensation reaction underlying peptide synthesis, is hindered in aqueous systems by the thermodynamic constraints associated with dehydration. This represents a key difficulty for the widely held view that prebiotic chemical evolution leading to the formation of the first biomolecules occurred in an oceanic environment. Recent evidence for the acceleration of chemical reactions at droplet interfaces led us to explore aqueous amino acid droplet chemistry. We report the formation of dipeptide isomer ions from free glycine or L-alanine at the air–water interface of aqueous microdroplets emanating from a single spray source (with or without applied potential) during their flight toward the inlet of a mass spectrometer. The proposed isomeric dipeptide ion is an oxazolidinone that takes fully covalent and ion-neutral complex forms. This structure is consistent with observed fragmentation patterns and its conversion to authentic dipeptide ions upon gentle collisions and for its formation from authentic dipeptides at ultra-low concentrations. It also rationalizes the results of droplet fusion experiments that show that the dipeptide isomer facilitates additional amide bond formation events, yielding authentic tri- through hexapeptides. We propose that the interface of aqueous microdroplets serves as a drying surface that shifts the equilibrium between free amino acids in favor of dehydration via stabilization of the dipeptide isomers. These findings offer a possible solution to the water paradox of biopolymer synthesis in prebiotic chemistry.