纳米技术
材料科学
纳米材料
催化作用
微型反应器
皮克林乳液
多相催化
乳状液
绿色化学
结构化
纳米颗粒
催化效率
纳米-
可扩展性
相(物质)
表面工程
能量转换
高效能源利用
纳米结构
环境友好型
表面改性
作者
Bokgi Seo,Jaewon Shin,Minkyoung Jang,Kyoungho Choi,Tengfei Pang,Fangrui Zhong,Junsu Kim
摘要
The assembly of functional nanomaterials at liquid-liquid interfaces offers a promising approach to address mass transfer and catalyst-recovery limitations in conventional biphasic catalytic systems. This strategy exploits engineered colloidal particles serving dual roles as emulsion stabilizers and catalytic sites, creating platforms with high interfacial area-to-volume ratios. These systems can exhibit improved reaction kinetics with efficient phase separation and catalyst recyclability while potentially operating under milder conditions that reduce energy consumption and waste generation. This review analyzes recent developments in the design, synthesis, and surface engineering of interfacially active nanocatalysts. It is examined structure-performance relationships governing catalytic efficiency and emulsion stability, assess industrial implementation challenges including scalability and economic viability, and evaluate prospects of Pickering emulsion-based microreactor platforms as enabling technologies for sustainable chemical processes aligned with green chemistry principles and circular economy frameworks.
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