Mechanically interlocked two-dimensional polymers

Madison I. Bardot; Cody W. Weyhrich; Zixiao Shi; Michael Traxler; Charlotte L. Stern; Jinlei Cui; David A. Muller; Matthew L. Becker; William R. Dichtel

doi:10.1126/science.ads4968

Mechanically interlocked two-dimensional polymers

Madison I. Bardot, Cody W. Weyhrich, Zixiao Shi, Michael Traxler, Charlotte L. Stern, Jinlei Cui, David A. Muller, Matthew L. Becker, William R. Dichtel^*

^*Corresponding author for this work

Chemistry

Research output: Contribution to journal › Article › peer-review

Abstract

Mechanical bonds arise between molecules that contain interlocked subunits, such as one macrocycle threaded through another. Within polymers, these linkages will confer distinctive mechanical properties and other emergent behaviors, but polymerizations that form mechanical bonds efficiently and use simple monomeric building blocks are rare. In this work, we introduce a solid-state polymerization in which one monomer infiltrates crystals of another to form a macrocycle and mechanical bond at each repeat unit of a two-dimensional (2D) polymer. This mechanically interlocked 2D polymer is formed as a layered solid that is readily exfoliated in common organic solvents, enabling spectroscopic characterization and atomic-resolution imaging using advanced electron microscopy techniques. The 2D mechanically interlocked polymer is easily prepared on multigram scales, which, along with its solution processibility, enables the facile fabrication of composite fibers with Ultem that exhibit enhanced stiffness and strength.

Original language	English (US)
Pages (from-to)	264-269
Number of pages	6
Journal	Journal of Bio-X Research
Volume	387
Issue number	6731
DOIs	https://doi.org/10.1126/science.ads4968
State	Published - Jan 17 2025

Funding

We acknowledge L. Felsenthal for her helpful discussions. This work is dedicated to the memory of J. Fraser Stoddart. This study received support from Defense Advanced Research Projects Agency (DARPA) under contract HR00112320041 (M.L.B. and W.R.D.); US National Science Foundation (NSF) grant ECCS-2025633 (Northwestern University shared instrumentation); NSF grants DMR-1719875 and DMR-2039380 (Cornell Center for Materials Research and PARADIM shared instrumentation); NSF grant MRI-1429155, the Weill Institute, the Kavli Institute at Cornell, and Cornell University (FEI Titan Themis 300 transmission electron microscope); NSF grant ECCS-2025633 and Northwestern University (IMSERC Crystallography Facility at Northwestern); NSF grant ECCS-2025064 and North Carolina Research Triangle Nanotechnology Network (Duke University Shared Materials Instrumentation Facility); US National Institutes of Health grants 1S10OD012016-01 and 1S10RR019071-01A1 (Northwestern University, nuclear magnetic resonance spectrometers); National Cancer Institute grant no. P30 CA060553 (Northwestern University shared instrumentation); Northwestern Trienens Institute for Sustainability and Energy at Northwestern (W.R.D., instrumentation grant); and the International Institute of Nanotechnology at Northwestern University, Ryan Fellowship (M.I.B.).

ASJC Scopus subject areas

Biomedical Engineering
General Biochemistry, Genetics and Molecular Biology
Computer Science Applications

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title = "Mechanically interlocked two-dimensional polymers",

abstract = "Mechanical bonds arise between molecules that contain interlocked subunits, such as one macrocycle threaded through another. Within polymers, these linkages will confer distinctive mechanical properties and other emergent behaviors, but polymerizations that form mechanical bonds efficiently and use simple monomeric building blocks are rare. In this work, we introduce a solid-state polymerization in which one monomer infiltrates crystals of another to form a macrocycle and mechanical bond at each repeat unit of a two-dimensional (2D) polymer. This mechanically interlocked 2D polymer is formed as a layered solid that is readily exfoliated in common organic solvents, enabling spectroscopic characterization and atomic-resolution imaging using advanced electron microscopy techniques. The 2D mechanically interlocked polymer is easily prepared on multigram scales, which, along with its solution processibility, enables the facile fabrication of composite fibers with Ultem that exhibit enhanced stiffness and strength.",

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AU - Bardot, Madison I.

AU - Weyhrich, Cody W.

AU - Shi, Zixiao

AU - Traxler, Michael

AU - Stern, Charlotte L.

AU - Cui, Jinlei

AU - Muller, David A.

AU - Becker, Matthew L.

AU - Dichtel, William R.

PY - 2025/1/17

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AB - Mechanical bonds arise between molecules that contain interlocked subunits, such as one macrocycle threaded through another. Within polymers, these linkages will confer distinctive mechanical properties and other emergent behaviors, but polymerizations that form mechanical bonds efficiently and use simple monomeric building blocks are rare. In this work, we introduce a solid-state polymerization in which one monomer infiltrates crystals of another to form a macrocycle and mechanical bond at each repeat unit of a two-dimensional (2D) polymer. This mechanically interlocked 2D polymer is formed as a layered solid that is readily exfoliated in common organic solvents, enabling spectroscopic characterization and atomic-resolution imaging using advanced electron microscopy techniques. The 2D mechanically interlocked polymer is easily prepared on multigram scales, which, along with its solution processibility, enables the facile fabrication of composite fibers with Ultem that exhibit enhanced stiffness and strength.

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Mechanically interlocked two-dimensional polymers

Abstract

Funding

ASJC Scopus subject areas

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