Mechanically Induced Opening–Closing Action of Binaphthyl Molecular Pliers: Digital Phase Transition versus Continuous Conformational Change

Reversible dynamic control of structure is a significant challenge in molecular nanotechnology. Previously, we have reported a mechanically induced continuous (analog) conformational variation in an amphiphilic binaphthyl, where closing of molecular pliers was achieved by compression of a molecular...

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Veröffentlicht in:	Chemphyschem 2017-06, Vol.18 (11), p.1470-1474
Hauptverfasser:	Mori, Taizo, Ishikawa, Daisuke, Yonamine, Yusuke, Fujii, Yoshihisa, Hill, Jonathan P., Ichinose, Izumi, Ariga, Katsuhiko, Nakanishi, Waka
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Sprache:	eng
Schlagworte:	biaryls chirality Compressing crystal growth Crystallization Discontinuity Dissolution Dynamic control Hand tools interfaces lipids Molecular structure Nanocrystals Nanotechnology Phase transitions Stresses
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container_title	Chemphyschem
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creator	Mori, Taizo Ishikawa, Daisuke Yonamine, Yusuke Fujii, Yoshihisa Hill, Jonathan P. Ichinose, Izumi Ariga, Katsuhiko Nakanishi, Waka
description	Reversible dynamic control of structure is a significant challenge in molecular nanotechnology. Previously, we have reported a mechanically induced continuous (analog) conformational variation in an amphiphilic binaphthyl, where closing of molecular pliers was achieved by compression of a molecular monolayer composed of these molecules at the air–water interface. In this work we report that a phase transition induced by an applied mechanical stress enables discontinuous digital (1/0) opening of simple binaphthyl molecular pliers. A lipid matrix at the air–water interface promotes the formation of quasi‐stable nanocrystals, in which binaphthyl molecules have an open transoid configuration. The crystallization/dissolution of quasi‐stable binaphthyl crystals with accompanying conformational change is reversible and repeatable. Open‐and‐shut case: Mechanical‐stimulus‐induced formation of quasi‐stable nanocrystals at the air–water interface enables conformational switching of a simple binaphthyl from cisoid to transoid (open to closed). The switching is reversible in an on/off manner, in contrast to a continuous conformational variation, and occurs only in mixed monolayers at the air–water interface, attesting to the importance of the medium for operation of this effect.
doi_str_mv	10.1002/cphc.201601144
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Previously, we have reported a mechanically induced continuous (analog) conformational variation in an amphiphilic binaphthyl, where closing of molecular pliers was achieved by compression of a molecular monolayer composed of these molecules at the air–water interface. In this work we report that a phase transition induced by an applied mechanical stress enables discontinuous digital (1/0) opening of simple binaphthyl molecular pliers. A lipid matrix at the air–water interface promotes the formation of quasi‐stable nanocrystals, in which binaphthyl molecules have an open transoid configuration. The crystallization/dissolution of quasi‐stable binaphthyl crystals with accompanying conformational change is reversible and repeatable. Open‐and‐shut case: Mechanical‐stimulus‐induced formation of quasi‐stable nanocrystals at the air–water interface enables conformational switching of a simple binaphthyl from cisoid to transoid (open to closed). 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Previously, we have reported a mechanically induced continuous (analog) conformational variation in an amphiphilic binaphthyl, where closing of molecular pliers was achieved by compression of a molecular monolayer composed of these molecules at the air–water interface. In this work we report that a phase transition induced by an applied mechanical stress enables discontinuous digital (1/0) opening of simple binaphthyl molecular pliers. A lipid matrix at the air–water interface promotes the formation of quasi‐stable nanocrystals, in which binaphthyl molecules have an open transoid configuration. The crystallization/dissolution of quasi‐stable binaphthyl crystals with accompanying conformational change is reversible and repeatable. Open‐and‐shut case: Mechanical‐stimulus‐induced formation of quasi‐stable nanocrystals at the air–water interface enables conformational switching of a simple binaphthyl from cisoid to transoid (open to closed). 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subjects	biaryls chirality Compressing crystal growth Crystallization Discontinuity Dissolution Dynamic control Hand tools interfaces lipids Molecular structure Nanocrystals Nanotechnology Phase transitions Stresses
title	Mechanically Induced Opening–Closing Action of Binaphthyl Molecular Pliers: Digital Phase Transition versus Continuous Conformational Change
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