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Breaking the photoswitch speed limit

Author

Listed:
  • Grace C. Thaggard

    (University of South Carolina)

  • Kyoung Chul Park

    (University of South Carolina)

  • Jaewoong Lim

    (University of South Carolina)

  • Buddhima K. P. Maldeni Kankanamalage

    (University of South Carolina)

  • Johanna Haimerl

    (University of South Carolina
    Technical University of Munich)

  • Gina R. Wilson

    (University of South Carolina)

  • Margaret K. McBride

    (University of South Carolina)

  • Kelly L. Forrester

    (University of South Carolina)

  • Esther R. Adelson

    (University of South Carolina)

  • Virginia S. Arnold

    (University of South Carolina)

  • Shehani T. Wetthasinghe

    (University of South Carolina)

  • Vitaly A. Rassolov

    (University of South Carolina)

  • Mark D. Smith

    (University of South Carolina)

  • Daniil Sosnin

    (Dartmouth College)

  • Ivan Aprahamian

    (Dartmouth College)

  • Manisha Karmakar

    (Jadavpur University)

  • Sayan Kumar Bag

    (Jadavpur University)

  • Arunabha Thakur

    (Jadavpur University)

  • Minjie Zhang

    (The Hong Kong University of Science and Technology)

  • Ben Zhong Tang

    (The Hong Kong University of Science and Technology
    The Chinese University of Hong Kong Shenzhen
    South China University of Technology
    Guangzhou Development District)

  • Jorge A. Castaño

    (Universidad del Valle)

  • Manuel N. Chaur

    (Universidad del Valle
    Universidad del Valle)

  • Michael M. Lerch

    (University of Groningen)

  • Roland A. Fischer

    (Technical University of Munich)

  • Joanna Aizenberg

    (Harvard University
    Harvard University)

  • Rainer Herges

    (University of Kiel)

  • Jean-Marie Lehn

    (Université de Strasbourg)

  • Natalia B. Shustova

    (University of South Carolina)

Abstract

The forthcoming generation of materials, including artificial muscles, recyclable and healable systems, photochromic heterogeneous catalysts, or tailorable supercapacitors, relies on the fundamental concept of rapid switching between two or more discrete forms in the solid state. Herein, we report a breakthrough in the “speed limit” of photochromic molecules on the example of sterically-demanding spiropyran derivatives through their integration within solvent-free confined space, allowing for engineering of the photoresponsive moiety environment and tailoring their photoisomerization rates. The presented conceptual approach realized through construction of the spiropyran environment results in ~1000 times switching enhancement even in the solid state compared to its behavior in solution, setting a record in the field of photochromic compounds. Moreover, integration of two distinct photochromic moieties in the same framework provided access to a dynamic range of rates as well as complementary switching in the material’s optical profile, uncovering a previously inaccessible pathway for interstate rapid photoisomerization.

Suggested Citation

  • Grace C. Thaggard & Kyoung Chul Park & Jaewoong Lim & Buddhima K. P. Maldeni Kankanamalage & Johanna Haimerl & Gina R. Wilson & Margaret K. McBride & Kelly L. Forrester & Esther R. Adelson & Virginia , 2023. "Breaking the photoswitch speed limit," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-43405-w
    DOI: 10.1038/s41467-023-43405-w
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    References listed on IDEAS

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