Delineating the pathways for the site-directed synthesis of individual nanoparticles on surfaces

Delineating the pathways for the site-directed synthesis of individual nanoparticles on surfaces

Although nanoparticles with exquisite properties have been synthesized for a variety of applications, their incorporation into functional devices is challenging owing to the difficulty in positioning them at specified sites on surfaces. In contrast with the conventional synthesis-then-assembly parad...

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Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 110; no. 3; pp. 887 - 891
Main Authors: Liu, Guoliang, Eichelsdoerfer, Daniel J., Rasin, Boris, Zhou, Yu, Brown, Keith A., Liao, Xing, Mirkin, Chad A.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 15-01-2013
National Acad Sciences
Subjects:
Aggregation
Annealing
Block copolymers
Chemical synthesis
Copolymers
Lithography
Materials
Metal ions
Metal particles
Metals
Nanoparticles
Nanotechnology
Physical Sciences
Polymers
Scanning electron microscopy
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Summary:Although nanoparticles with exquisite properties have been synthesized for a variety of applications, their incorporation into functional devices is challenging owing to the difficulty in positioning them at specified sites on surfaces. In contrast with the conventional synthesis-then-assembly paradigm, scanning probe block copolymer lithography can pattern precursor materials embedded in a polymer matrix and synthesize desired nanoparticles on site, offering great promise for incorporating nanoparticles into devices. This technique, however, is extremely limited from a materials standpoint. To develop a materials-general method for synthesizing nanoparticles on surfaces for broader applications, a mechanistic understanding of polymer-mediated nanoparticle formation is crucial. Here, we design a four-step synthetic process that enables independent study of the two most critical steps for synthesizing single nanoparticles on surfaces: phase separation of precursors and particle formation. Using this process, we elucidate the importance of the polymer matrix in the diffusion of metal precursors to form a single nanoparticle and the three pathways that the precursors undergo to form nanoparticles. Based on this mechanistic understanding, the synthetic process is generalized to create metal (Au, Ag, Pt, and Pd), metal oxide (Fe ₂O ₃, Co ₂O ₃, NiO, and CuO), and alloy (AuAg) nanoparticles. This mechanistic understanding and resulting process represent a major advance in scanning probe lithography as a tool to generate patterns of tailored nanoparticles for integration with solid-state devices.
Bibliography:http://dx.doi.org/10.1073/pnas.1220689110
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Author contributions: G.L. and C.A.M. designed research; G.L., D.J.E., B.R., Y.Z., K.A.B., and X.L. performed research; G.L. contributed new reagents/analytic tools; G.L., D.J.E., and B.R. analyzed data; and G.L., D.J.E., B.R., K.A.B., and C.A.M. wrote the paper.
Contributed by Chad A. Mirkin, November 27, 2012 (sent for review October 9, 2012)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1220689110