Building superlattices from individual nanoparticles via template-confined DNA-mediated assembly

Lin, Qing-Yuan; Mason, Jarad A.; Li, Zhongyang; Zhou, Wenjie; O’Brien, Matthew N.; Brown, Keith A.; Jones, Matthew R.; Butun, Serkan; Lee, Byeongdu; Dravid, Vinayak P.; Aydin, Koray; Mirkin, Chad A.

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American Association for the Advancement of Science, Science, 6376(359), p. 669-672, 2018

DOI: 10.1126/science.aaq0591

Spherical Nucleic Acids, p. 1195-1208, 2020

DOI: 10.4324/9780429200151-72

Spherical Nucleic Acids, p. 1195-1208, 2020

DOI: 10.1201/9781003056706-72

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Building superlattices from individual nanoparticles via template-confined DNA-mediated assembly

Journal article published in 2018 by Qing-Yuan Lin

, Jarad A. Mason

, Zhongyang Li

, Wenjie Zhou

, Matthew N. O’Brien

, Keith A. Brown

, Matthew R. Jones

, Serkan Butun

, Byeongdu Lee

, Vinayak P. Dravid

, Koray Aydin

, Chad A. Mirkin

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Abstract

Programmed nanoparticle stacking A polymer pore template can control the order of assembly of nanoparticles into well-defined stacks and create superlattices. Lin et al. used DNA strands on gold nanoparticles to control interparticle distance. The DNA strands contained modified adenines with more rigid ribose groups that formed stronger base pairs. The height of the stacks of three different types of gold nanoparticle could be changed with different solvents, which in turn changed their optical response. Science , this issue p. 669

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Building superlattices from individual nanoparticles via template-confined DNA-mediated assembly

Abstract