Divalent Multilinking Bonds Control Growth and Morphology of Nanopolymers

Yan Xiong, Zhiwei Lin, Deniz Mostarac, Brian Minevich, Qiuyuan Peng, Guolong Zhu, Pedro A. Sánchez, Sofia Kantorovich, Yonggang Ke, Oleg Gang (Corresponding author)

Publications: Contribution to journalArticlePeer Reviewed

Abstract

Assembly of nanoscale objects into linear architectures resembling molecular polymers is a basic organization resulting from divalent interactions. Such linear architectures occur for particles with two binding patches on opposite sides, known as Janus particles. However, unlike molecular systems where valence bonds can be envisioned as pointlike interactions nanoscale patches are often realized through multiple molecular linkages. The relationship between the characteristics of these linkages, the resulting interpatch connectivity, and assembly morphology is not well-explored. Here, we investigate assembly behavior of model divalent nanomonomers, DNA nanocuboid with tailorable multilinking bonds. Our study reveals that the characteristics of individual molecular linkages and their collective properties have a profound effect on nanomonomer reactivity and resulting morphologies. Beyond linear nanopolymers, a common signature of divalent nanomonomers, we observe an effective valence increase as linkages lengthened, leading to the nanopolymer bundling. The experimental findings are rationalized by molecular dynamics simulations.

Original languageEnglish
Pages (from-to)10547-10554
Number of pages8
JournalNano Letters
Volume21
Issue number24
Early online date14 Oct 2021
DOIs
Publication statusPublished - 22 Dec 2021

Austrian Fields of Science 2012

  • 103043 Computational physics
  • 103023 Polymer physics
  • 210004 Nanomaterials

Keywords

  • ASSEMBLIES
  • COLLOIDAL NANOCRYSTALS
  • CRYSTALLIZATION
  • DNA
  • DNA nanotechnology
  • NANOCUBES
  • NANOPARTICLES
  • ORGANIZATION
  • PATCHY PARTICLES
  • POLYMERIZATION
  • Patchy particles
  • REALIZATION
  • phase behavior
  • polymerization
  • self-assembly
  • Molecular Dynamics Simulation
  • Polymers/chemistry
  • DNA/chemistry

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