One-Pot Self-Assembly of Sequence-Controlled Mesoporous Heterostructures via Structure-Directing Agents

Multimaterial heterostructures have led to characteristics surpassing the individual components. Nature controls the architecture and placement of multiple materials through biomineralization of nanoparticles (NPs); however, synthetic heterostructure formation remains limited and generally departs f...

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Published in:ACS nano Vol. 18; no. 31; pp. 20133 - 20141
Main Authors: Larison, Taylor, Williams, Eric R., Wright, Mason, Zhang, Mengxue, Tengco, John, Boebinger, Matthew G., Tang, Chuanbing, Stefik, Morgan
Format: Journal Article
Language:English
Published: United States American Chemical Society 29-07-2024
American Chemical Society (ACS)
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Summary:Multimaterial heterostructures have led to characteristics surpassing the individual components. Nature controls the architecture and placement of multiple materials through biomineralization of nanoparticles (NPs); however, synthetic heterostructure formation remains limited and generally departs from the elegance of self-assembly. Here, a class of block polymer structure-directing agents (SDAs) are developed containing repeat units capable of persistent (covalent) NP interactions that enable the direct fabrication of nanoscale porous heterostructures, where a single material is localized at the pore surface as a continuous layer. This SDA binding motif (design rule 1) enables sequence-controlled heterostructures, where the composition profile and interfaces correspond to the synthetic addition order. This approach is generalized with 5 material sequences using an SDA with only persistent SDA-NP interactions (“P-NP1–NP2”; NPi = TiO2, Nb2O5, ZrO2). Expanding these polymer SDA design guidelines, it is shown that the combination of both persistent and dynamic (noncovalent) SDA-NP interactions (“PD-NP1–NP2”) improves the production of uniform interconnected porosity (design rule 2). The resulting competitive binding between two segments of the SDA (P- vs D-) requires additional time for the first NP type (NP1) to reach and covalently attach to the SDA (design rule 3). The combination of these three design rules enables the direct self-assembly of heterostructures that localize a single material at the pore surface while preserving continuous porosity.
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USDOE Office of Science (SC), Basic Energy Sciences (BES). Scientific User Facilities (SUF)
National Science Foundation (NSF)
AC05-00OR22725; CNMS2023-R-01970; DMR-1752615; ECCS-2025064
ISSN:1936-0851
1936-086X
1936-086X
DOI:10.1021/acsnano.4c01855