Supramolecular Rosette Intermediated Homochiral Double Helix

Overview

Journal Nat Commun

Specialty Biology

Date 2025 Feb 17

PMID 39962065

Authors

Tiejun Li

Dian Niu

Lukang Ji

Qian Li

Bo Guan

Hanxiao Wang

Guanghui Ouyang

Minghua Liu

Affiliations

Soon will be listed here.

Abstract

Precise organization of organic molecules into homochiral double-helix remains a challenge due to the difficulty in controlling both self-assembly process and chirality transfer across length scales. Here, we report that a type of bisnaphthalene bisurea molecule could assemble into chirality-controlled nanoscale double-helices by a supramolecular rosette-intermediated hierarchical self-assembly mechanism. A solvent-mixing self-assembly protocol is adopted to direct bisnaphthalene bisurea cyclization into chiral discrete rosettes through cooperative intramolecular and intermolecular hydrogen bonds. Controlled hexagonal packing of rosettes at higher concentrations gives one-dimensional single-stranded nanofibers, which intertwine into well-defined double-helix nanostructures with preferred chirality that depends on the absolute configurations of bisnaphthalene bisurea. The hierarchical organization of bisnaphthalene bisurea molecules enables effective excitation energy delocalization within the double-helix, which contributes to near-unity energy transfer from double-helix to adsorbed acceptor dyes even in donor/acceptor ratios over 1000, leading to bright circularly polarized luminescence from the originally achiral acceptor. The experimental and theoretical simulation results not only provide a hierarchical strategy to fabricate homochiral double-helix but also bring insights in understanding the high-efficiency light-harvesting process in photosystem II.

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