Visible‐Light‐Driven Halogen Bond Donor Based Molecular Switches: From Reversible Unwinding to Handedness Inversion in Self‐Organized Soft Helical Superstructures

Wang, Hao; Bisoyi, Hari Krishna; Li, Bingxiang; McConney, Michael E.; Bunning, Timothy J.; Li, Quan

doi:10.1002/anie.201913977

Cited by 83 publications

(57 citation statements)

References 44 publications

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“…[ 13 ] Therefore, liquid crystals constitute an effective host medium for molecular motors and switches. [ 14–16 ] Chiral molecular switches can drive dynamic helix inversion in liquid crystals, [ 17–24 ] and artificial molecular motors also induce the formation of chiral nematic liquid crystals that respond to light with large changes in pitch and in the orientation of the helical axis, usually also with chiral inversion at the photostationary state. [ 25,26 ] Motor‐doped cholesteric liquid crystals have supported the discovery of rotating surfaces, [ 27–29 ] supramolecular vortices, [ 30 ] swimming [ 31 ] and reconfigurable chiral droplets, [ 32 ] and adaptive optical materials.…”

Section: Figurementioning

confidence: 99%

Helix Inversion Controlled by Molecular Motors in Multistate Liquid Crystals

et al. 2020

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Artificial molecular motors and switches are called to contribute in setting materials in motion. [1-5] Ongoing efforts to enable transmission of motion and allow molecular machines to work at larger length scales involve their integration in hydrogels, [6-8] self-assembled monolayers, [9] artificial muscles, [10,11] and polymer materials. [12] The long-range organization and fluidity of liquid crystals accounts for their high responsiveness to small changes in molecular structure or composition, with a special sensitivity to changes in chirality. [13] Therefore, liquid crystals constitute an effective host medium for molecular motors and switches. [14-16] Chiral molecular switches can drive dynamic helix inversion in liquid crystals, [17-24] and artificial molecular motors also induce the formation of chiral nematic liquid crystals that respond to light with large changes in pitch and in the orientation of the helical axis, usually also with chiral inversion at the photostationary state. [25,26] Motordoped cholesteric liquid crystals have supported the discovery of rotating surfaces, [27-29] supramolecular vortices, [30] swimming [31] and reconfigurable chiral droplets, [32] and adaptive optical materials. [33,34] Notably, while being at the forefront of light-responsive and adaptive materials, to date motor-doped liquid crystals have been used primarily for their ability to convert from one helix to another, reversibly. These earlier studies have involved "second generation" motors, for which only the expression of two states was possible, because only two isomers of these motors can be distinguished at room temperature. [35,36] Here, we report the motion of the so-called "first generation" molecular motor in liquid crystals, in a cyclic behavior that involves four distinct isomeric states. These motors induce light-responsive helices in liquid crystals, which readily undergo photomodulation of the liquid crystal phase, including helix inversion. While multistate liquid crystal helices can be designed by mixing chiral dopants, [37,38] using a single chiral dopant-for example, by incorporating multiple light-switchable units, [14,39,40] is a better option as this prevents solubility issues and offers better options for rational design, as predictions on the pitch formed by a mixture of chiral dopants lack reliability, particularly at larger concentrations. Key to the design of molecular motors that are able to drive multistate and photoinvertible helices is that each of the motor states displays a distinctively different shape, i.e., either

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Section: Figurementioning

confidence: 99%

Helix Inversion Controlled by Molecular Motors in Multistate Liquid Crystals

et al. 2020

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“…Stimuli‐responsive molecules are the basis of information processing in biological as well as synthetic complex systems. Among them, photochromic molecules are particularly attractive for the ability to convert between (at least) two states by noninvasive and rapid optical stimuli with a potential of high spatial and temporal resolution . Additionally, multiple photochromic molecules have been developed, which in addition to light respond to a secondary stimulus, such as the presence of ions, oxidants/reductants, or acids/bases .…”

Section: Figurementioning

confidence: 99%

Proton‐Gated Ring‐Closure of a Negative Photochromic Azulene‐Based Diarylethene

et al. 2020

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Proton-responsive photochromic molecules are attractive for their ability to react on non-invasive rapid optical stimuli and the importance of protonation/deprotonation processes in various fields. Conventionally, their acidic/basic sites are on hetero-atoms, which are orthogonal to the photoactive p-center. Here, we incorporate azulene, an acid-sensitive pure hydrocarbon, into the skeleton of a diarylethene-type photoswitch. The latter exhibits a novel proton-gated negative photochromic ring-closure and its optical response upon protonation in both open and closed forms is much more pronounced than those of diarylethene photoswitches with hetero-atom based acidic/basic moieties. The unique behavior of the new photoswitch can be attributed to direct protonation on its p-system, supported by 1 H NMR and theoretical calculations. Our results demonstrate the great potential of integrating non-alternant hydrocarbons into photochromic systems for the development of multi-responsive molecular switches.

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“…Auf Stimuli reagierende Moleküle sind die Grundlage der Informationsverarbeitung in biologischen wie auch synthetischen, komplexen Systemen. Unter ihnen sind photochrome Moleküle aufgrund ihrer Fähigkeit zur Umwandlung zwischen (mindestens) zwei Zuständen durch nicht‐invasive und schnelle optische Stimuli bei gleichzeitig potentiell hoher räumlicher und zeitlicher Auflösung besonders attraktiv . Darüber hinaus wurden photochrome Moleküle entwickelt, die zusätzlich zu Licht auf einen sekundären Stimulus reagieren, beispielsweise auf die Anwesenheit von Ionen, Oxidations‐/Reduktionsmitteln, oder Säuren/Basen .…”

Section: Figureunclassified

Protonenvermittelter Ringschluss eines negativ photochromen, Azulen‐basierten Diarylethens

et al. 2020

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Auf Protonen ansprechende photochrome Moleküle sind aufgrund ihrer Fähigkeit, auf nicht-invasive schnelle optische Stimuli zu reagieren, und wegen der ubiquitären Bedeutung von Protonierungs-und Deprotonierungsprozessen, sehr interessant. Üblicherweise befinden sich die sauren/basischen Stellen dieser Moleküle an Heteroatomen, die orthogonal zum photoaktiven p-Zentrum ausgerichtet sind. In dieser Arbeit wird Azulen, ein protonensensitiver reiner Kohlenwasserstoff, in das Gerüst eines Diarylethen-Photoschalters eingebaut. Dieser zeigt einen bisher ungekannten, protonenvermittelten, negativ photochromen Ringschluss. Veränderungen seiner optischen Eigenschaften durch Protonierung, sowohl in der offenen, als auch in der geschlossenen Form, sind viel ausgeprägter als die von Diarylethen-Photoschaltern mit Säure/Base-Gruppen auf Heteroatombasis. Das einzigartige Verhalten des neuen Photoschalters kann auf die direkte Protonierung seines p-Systems zurückgeführt werden, was sowohl durch 1 H-NMR als auch durch theoretische Berechnungen belegt wird. Unsere Ergebnisse zeigen das große Potenzial der Einbindung nicht-alternierender Kohlenwasserstoffe in photochrome Systeme für die Entwicklung von molekularen Schaltern, die auf unterschiedliche Stimuli reagieren.

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Visible‐Light‐Driven Halogen Bond Donor Based Molecular Switches: From Reversible Unwinding to Handedness Inversion in Self‐Organized Soft Helical Superstructures

Cited by 83 publications

References 44 publications

Helix Inversion Controlled by Molecular Motors in Multistate Liquid Crystals

Helix Inversion Controlled by Molecular Motors in Multistate Liquid Crystals

Proton‐Gated Ring‐Closure of a Negative Photochromic Azulene‐Based Diarylethene

Protonenvermittelter Ringschluss eines negativ photochromen, Azulen‐basierten Diarylethens

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