Lattice Mismatch in Crystalline Nanoparticle Thin Films

Lattice Mismatch in Crystalline Nanoparticle Thin Films

For atomic thin films, lattice mismatch during heteroepitaxy leads to an accumulation of strain energy, generally causing the films to irreversibly deform and generate defects. In contrast, more elastically malleable building blocks should be better able to accommodate this mismatch and the resultin...

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Bibliographic Details
Published in:Nano letters Vol. 18; no. 1
Main Authors: Gabrys, Paul A., Seo, Soyoung E., Wang, Mary X., Oh, EunBi, Macfarlane, Robert J., Mirkin, Chad A.
Format: Journal Article
Language:English
Published: United States American Chemical Society 22-12-2017
Subjects:
epitaxy
lattice mismatch
MATERIALS SCIENCE
nanoparticle
self-assembly
thin film
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Summary:For atomic thin films, lattice mismatch during heteroepitaxy leads to an accumulation of strain energy, generally causing the films to irreversibly deform and generate defects. In contrast, more elastically malleable building blocks should be better able to accommodate this mismatch and the resulting strain. In our work, that hypothesis is tested by utilizing DNA-modified nanoparticles as “soft,” programmable atom equivalents to grow a heteroepitaxial colloidal thin film. Calculations of interaction potentials, small-angle X-ray scattering data, and electron microscopy images show that the oligomer corona surrounding a particle core can deform and rearrange to store elastic strain up to ±7.7% lattice mismatch, substantially exceeding the ±1% mismatch tolerated by atomic thin films. Importantly, these DNA-coated particles dissipate strain both elastically through a gradual and coherent relaxation/ broadening of the mismatched lattice parameter and plastically (irreversibly) through the formation of dislocations or vacancies. These data also suggest that the DNA cannot be extended as readily as compressed, and thus the thin films exhibit distinctly different relaxation behavior in the positive and negative lattice mismatch regimes. These observations provide a more general understanding of how utilizing rigid building blocks coated with soft compressible polymeric materials can be used to control nano- and microstructure.
Bibliography:USDOE Office of Science (SC), Basic Energy Sciences (BES)
US Department of the Navy, Office of Naval Research (ONR)
Young Investigator Research Program
National Science Foundation (NSF)
FA9550-16-1-0150; FA9950-17-1-0348; FA9550-17-1-0288; N00014-15-1-0043; SC0000989; AC02-06CH11357; DMR-1121262; NSF 1122374
US Air Force Office of Scientific Research (AFOSR)
ISSN:1530-6984
1530-6992