材料科学
纳米技术
光催化
生物矿化
锐钛矿
成核
微晶
纳米颗粒
分散性
化学工程
化学
催化作用
有机化学
工程类
高分子化学
冶金
作者
Jinrong Ma,Biao Jin,Kathryn N. Guye,Md Emtias Chowdhury,Nada Y. Naser,Chun‐Long Chen,James J. De Yoreo,François Baneyx
标识
DOI:10.1002/adma.202207543
摘要
Sequence-defined foldamers that self-assemble into well-defined architectures are promising scaffolds to template inorganic mineralization. However, it has been challenging to achieve robust control of nucleation and growth without sequence redesign or extensive experimentation. Here, peptoid nanotubes functionalized with a panel of solid-binding proteins are used to mineralize homogeneously distributed and monodisperse anatase nanocrystals from the water-soluble TiBALDH precursor. Crystallite size is systematically tuned between 1.4 and 4.4 nm by changing protein coverage and the identity and valency of the genetically engineered solid-binding segments. The approach is extended to the synthesis of gold nanoparticles and, using a protein encoding both material-binding specificities, to the fabrication of titania/gold nanocomposites capable of photocatalysis under visible-light illumination. Beyond uncovering critical roles for hierarchical organization and denticity on solid-binding protein mineralization outcomes, the strategy described herein should prove valuable for the fabrication of hierarchical hybrid materials incorporating a broad range of inorganic components.
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