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Bibliographic Details
Main Authors: Koehler, Lara, Eder, Markus, Ouazan-Reboul, Vincent, Karfusehr, Christoph, Zelenskiy, Andrey, Ronceray, Pierre, Simmel, Friedrich C., Lenz, Martin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.13073
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author Koehler, Lara
Eder, Markus
Ouazan-Reboul, Vincent
Karfusehr, Christoph
Zelenskiy, Andrey
Ronceray, Pierre
Simmel, Friedrich C.
Lenz, Martin
author_facet Koehler, Lara
Eder, Markus
Ouazan-Reboul, Vincent
Karfusehr, Christoph
Zelenskiy, Andrey
Ronceray, Pierre
Simmel, Friedrich C.
Lenz, Martin
contents The self-assembly of complex structures from engineered subunits is a major goal of nanotechnology, but controlling their size becomes increasingly difficult in larger assemblies. Existing strategies present significant challenges, among which the use of multiple subunit types or the precise control of their shape and mechanics. Here we introduce an alternative approach based on identical subunits whose interactions promote crystals, but also favor crystalline defects. We theoretically show that topological restrictions on the scope of these defects in large assemblies imply that the assembly size is controlled by the magnitude of the defect-inducing interaction. Using DNA origami, we experimentally demonstrate both size and shape control in two-dimensional disk- and fiber-like assemblies. Our basic concept of defect engineering could be generalized well beyond these simple examples, and thus provide a broadly applicable scheme to control self-assembly.
format Preprint
id arxiv_https___arxiv_org_abs_2504_13073
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Topological defect engineering enables size and shape control in self-assembly
Koehler, Lara
Eder, Markus
Ouazan-Reboul, Vincent
Karfusehr, Christoph
Zelenskiy, Andrey
Ronceray, Pierre
Simmel, Friedrich C.
Lenz, Martin
Soft Condensed Matter
The self-assembly of complex structures from engineered subunits is a major goal of nanotechnology, but controlling their size becomes increasingly difficult in larger assemblies. Existing strategies present significant challenges, among which the use of multiple subunit types or the precise control of their shape and mechanics. Here we introduce an alternative approach based on identical subunits whose interactions promote crystals, but also favor crystalline defects. We theoretically show that topological restrictions on the scope of these defects in large assemblies imply that the assembly size is controlled by the magnitude of the defect-inducing interaction. Using DNA origami, we experimentally demonstrate both size and shape control in two-dimensional disk- and fiber-like assemblies. Our basic concept of defect engineering could be generalized well beyond these simple examples, and thus provide a broadly applicable scheme to control self-assembly.
title Topological defect engineering enables size and shape control in self-assembly
topic Soft Condensed Matter
url https://arxiv.org/abs/2504.13073