Abstract

We report a virus-based scaffold for the synthesis of single-crystal ZnS, CdS, and freestanding chemically ordered CoPt and FePt nanowires, with the means of modifying substrate specificity through standard biological methods. Peptides (selected through an evolutionary screening process) that exhibit control of composition, size, and phase during nanoparticle nucleation have been expressed on the highly ordered filamentous capsid of the M13 bacteriophage. The incorporation of specific, nucleating peptides into the generic scaffold of the M13 coat structure provides a viable template for the directed synthesis of semiconducting and magnetic materials. Removal of the viral template by means of annealing promoted oriented aggregation-based crystal growth, forming individual crystalline nanowires. The unique ability to interchange substrate-specific peptides into the linear self-assembled filamentous construct of the M13 virus introduces a material tunability that has not been seen in previous synthetic routes. Therefore, this system provides a genetic toolkit for growing and organizing nanowires from semiconducting and magnetic materials.

Keywords

NanowireNucleationMaterials scienceNanotechnologyNanoparticleScaffoldCapsidSubstrate (aquarium)Synthetic biologyVirusChemistryBioinformaticsBiologyComputer science

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Publication Info

Year
2004
Type
article
Volume
303
Issue
5655
Pages
213-217
Citations
964
Access
Closed

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Cite This

Chuanbin Mao, Daniel J. Solis, Brian D. Reiss et al. (2004). Virus-Based Toolkit for the Directed Synthesis of Magnetic and Semiconducting Nanowires. Science , 303 (5655) , 213-217. https://doi.org/10.1126/science.1092740

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DOI
10.1126/science.1092740