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Flash-Thermal Shock Synthesis of Single Atoms in Ambient Air

Dong‐Ha Kim, Jun‐Hwe Cha, Sanggyu Chong, Su‐Ho Cho, Hamin Shin, Jaewan Ahn, Dogyeong Jeon, Jihan Kim, Sung‐Yool Choi, Il‐Doo Kim

2023ACS Nano31 citationsDOI

Abstract

Single-atom catalysts feature interesting catalytic activity toward applications that rely on surface reactions such as electrochemical energy storage, catalysis, and gas sensors. However, conventional synthetic approaches for such catalysts require extended periods of high-temperature annealing in vacuum systems, limiting their throughput and increasing their production cost. Herein, we report an ultrafast flash-thermal shock (FTS)-induced annealing technique (temperature > 2850 °C, <10 ms duration, and ramping/cooling rates of ∼10 5 K/s) that operates in an ambient-air environment to prepare single-atom-stabilized N-doped graphene. Melamine is utilized as an N-doping source to provide thermodynamically favorable metal–nitrogen bonding sites, resulting in a uniform and high-density atomic distribution of single metal atoms. To demonstrate the practical utility of the single-atom-stabilized N-doped graphene produced by the FTS method, we showcased their chemiresistive gas sensing capabilities and electrocatalytic activities. Overall, the air-ambient, ultrafast, and versatile (e.g., Co, Ni, Pt, and Co–Ni dual metal) FTS method provides a general route for high-throughput, large area, and vacuum-free manufacturing of single-atom catalysts.

Topics & Concepts

CatalysisMaterials scienceGrapheneDopingAtom (system on chip)NanotechnologyElectrochemistryAnnealing (glass)MetalChemical engineeringChemical physicsElectrodeOptoelectronicsPhysical chemistryChemistryOrganic chemistryEmbedded systemEngineeringMetallurgyComputer scienceComposite materialGraphene research and applicationsElectrocatalysts for Energy ConversionDiamond and Carbon-based Materials Research
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