Assembly and Chiral Memory Effects of Dynamic Macroscopic Supramolecular Helices

Macroscopic enantiomerically pure helical supramolecular fibers are bottom‐up assembled in aqueous media from a chiral π‐electron donor template and an achiral π‐electron acceptor. The helices can be assembled to the sub‐millimeter scale with controlled handedness. These dynamic supramolecular archi...

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Published in	Chemistry : a European journal Vol. 24; no. 62; pp. 16553 - 16557
Main Authors	Yuan, Tianyu, Sun, Zhimin, Mu, Anthony U., Zeng, Minxiang, Kalin, Alexander J., Cheng, Zhengdong, Olson, Mark A., Fang, Lei
Format	Journal Article
Language	English
Published	Germany Wiley Subscription Services, Inc 07.11.2018
Subjects	Chemistry chiral memory donor–acceptor systems Electrons Fibers Handedness helical structures Helices self-assembly supramolecular chemistry self-assembly donor-acceptor systems supramolecular chemistry chiral memory helical structures
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Abstract	Macroscopic enantiomerically pure helical supramolecular fibers are bottom‐up assembled in aqueous media from a chiral π‐electron donor template and an achiral π‐electron acceptor. The helices can be assembled to the sub‐millimeter scale with controlled handedness. These dynamic supramolecular architectures allow for a quantitative exchange of the chiral donor template with achiral analogues. During this process, a chiral memory effect was observed, affording enantiomerically pure helices composed entirely of achiral components. Macroscopic enantiomerically pure helical supramolecular fibers were bottom‐up assembled in aqueous media from a chiral π‐electron donor template and an achiral π‐electron acceptor. The helices can be assembled to the sub‐millimeter scale with controlled handedness.
AbstractList	Macroscopic enantiomerically pure helical supramolecular fibers are bottom‐up assembled in aqueous media from a chiral π‐electron donor template and an achiral π‐electron acceptor. The helices can be assembled to the sub‐millimeter scale with controlled handedness. These dynamic supramolecular architectures allow for a quantitative exchange of the chiral donor template with achiral analogues. During this process, a chiral memory effect was observed, affording enantiomerically pure helices composed entirely of achiral components. Macroscopic enantiomerically pure helical supramolecular fibers are bottom‐up assembled in aqueous media from a chiral π‐electron donor template and an achiral π‐electron acceptor. The helices can be assembled to the sub‐millimeter scale with controlled handedness. These dynamic supramolecular architectures allow for a quantitative exchange of the chiral donor template with achiral analogues. During this process, a chiral memory effect was observed, affording enantiomerically pure helices composed entirely of achiral components. Macroscopic enantiomerically pure helical supramolecular fibers were bottom‐up assembled in aqueous media from a chiral π‐electron donor template and an achiral π‐electron acceptor. The helices can be assembled to the sub‐millimeter scale with controlled handedness. Macroscopic enantiomerically pure helical supramolecular fibers are bottom-up assembled in aqueous media from a chiral π-electron donor template and an achiral π-electron acceptor. The helices can be assembled to the sub-millimeter scale with controlled handedness. These dynamic supramolecular architectures allow for a quantitative exchange of the chiral donor template with achiral analogues. During this process, a chiral memory effect was observed, affording enantiomerically pure helices composed entirely of achiral components.Macroscopic enantiomerically pure helical supramolecular fibers are bottom-up assembled in aqueous media from a chiral π-electron donor template and an achiral π-electron acceptor. The helices can be assembled to the sub-millimeter scale with controlled handedness. These dynamic supramolecular architectures allow for a quantitative exchange of the chiral donor template with achiral analogues. During this process, a chiral memory effect was observed, affording enantiomerically pure helices composed entirely of achiral components.
Author	Yuan, Tianyu Olson, Mark A. Zeng, Minxiang Cheng, Zhengdong Kalin, Alexander J. Fang, Lei Sun, Zhimin Mu, Anthony U.
Author_xml	– sequence: 1 givenname: Tianyu orcidid: 0000-0002-6698-5178 surname: Yuan fullname: Yuan, Tianyu organization: Texas A&M University – sequence: 2 givenname: Zhimin surname: Sun fullname: Sun, Zhimin organization: Tianjin University – sequence: 3 givenname: Anthony U. orcidid: 0000-0002-7689-4413 surname: Mu fullname: Mu, Anthony U. organization: Texas A&M University – sequence: 4 givenname: Minxiang orcidid: 0000-0002-3513-9200 surname: Zeng fullname: Zeng, Minxiang organization: Texas A&M University – sequence: 5 givenname: Alexander J. orcidid: 0000-0003-1355-2018 surname: Kalin fullname: Kalin, Alexander J. organization: Texas A&M University – sequence: 6 givenname: Zhengdong orcidid: 0000-0001-7720-1909 surname: Cheng fullname: Cheng, Zhengdong organization: Texas A&M University – sequence: 7 givenname: Mark A. orcidid: 0000-0003-0398-5063 surname: Olson fullname: Olson, Mark A. email: molson@tju.edu.cn organization: Tianjin University – sequence: 8 givenname: Lei orcidid: 0000-0003-4757-5664 surname: Fang fullname: Fang, Lei email: fang@chem.tamu.edu organization: Texas A&M University
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/30089198$$D View this record in MEDLINE/PubMed
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Snippet	Macroscopic enantiomerically pure helical supramolecular fibers are bottom‐up assembled in aqueous media from a chiral π‐electron donor template and an achiral... Macroscopic enantiomerically pure helical supramolecular fibers are bottom-up assembled in aqueous media from a chiral π-electron donor template and an achiral...
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SubjectTerms	Chemistry chiral memory donor–acceptor systems Electrons Fibers Handedness helical structures Helices self-assembly supramolecular chemistry
Title	Assembly and Chiral Memory Effects of Dynamic Macroscopic Supramolecular Helices
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