Detour to success: photoswitching via indirect excitation

Kim Kuntze; Jussi Isokuortti; Jacob J. van der Wal; Timo Laaksonen; Stefano Crespi; Nikita A. Durandin; Arri Priimagi

doi:10.1039/d4sc02538e

Detour to success: photoswitching via indirect excitation

Kim Kuntze
, Jussi Isokuortti
, Jacob J. van der Wal
, Timo Laaksonen
, Stefano Crespi^*
, Nikita A. Durandin^*
, Arri Priimagi^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

21 Citations (Scopus)

16 Downloads (Pure)

Abstract

Photoswitchable molecules that undergo nanoscopic changes upon photoisomerisation can be harnessed to control macroscopic properties such as colour, solubility, shape, and motion of the systems they are incorporated into. These molecules find applications in various fields of chemistry, physics, biology, and materials science. Until recently, research efforts have focused on the design of efficient photoswitches responsive to low-energy (red or near-infrared) irradiation, which however may compromise other molecular properties such as thermal stability and robustness. Indirect isomerisation methods enable photoisomerisation with low-energy photons without altering the photoswitch core, and also open up new avenues in controlling the thermal switching mechanism. In this perspective, we present the state of the art of five indirect excitation methods: two-photon excitation, triplet sensitisation, photon upconversion, photoinduced electron transfer, and indirect thermal methods. Each impacts our understanding of the fundamental physicochemical properties of photochemical switches, and offers unique application prospects in biomedical technologies and beyond.

Original language	English
Article number	11684
Journal	Chemical Science
Volume	15
Issue number	30
DOIs	https://doi.org/10.1039/d4sc02538e
Publication status	Published - 2024
Publication type	A1 Journal article-refereed

Funding

We gratefully acknowledge the financial support offered by the European Research Council (Consolidator projects MULTIMODAL, No. 101045223, for A. P. and PADRE, No. 101001016, for T. L.). We also thank the Research Council of Finland for their support through the Center of Excellence Programme on Life-Inspired Hybrid Materials Research, LIBER, No. 346107 (A. P.) and Flagship Programme on Photonics Research and Innovation, PREIN, No. 320165 (A. P.; T. L.), and Academy Research Fellowship project, No. 354792 (N. A. D). S. C. thanks the Swedish Vetenskapsr\u00E5det for a Starting Grant (2021-05414). J. I. gratefully acknowledges the Finnish Academy of Science and Letters for a Foundations' Post Doc Pool grant.

Funders	Funder number
Finnish Academy of Science and Letters for a Foundations
European Research Council	101001016, 101045223
European Research Council
Strategic Research Council at the Research Council of Finland	320165, 354792, 346107
Strategic Research Council at the Research Council of Finland
Vetenskapsrådet (Swedish Research Council)	2021-05414

Publication forum classification

Publication forum level 3

ASJC Scopus subject areas

General Chemistry

Access to Document

10.1039/d4sc02538eLicence: CC BY

Detour to successFinal published version, 906 KBLicence: CC BY

https://urn.fi/URN:NBN:fi:tuni-202408148108Licence: CC BY

Cite this

@article{d4b754766ef04a208278420a34a30f1c,

title = "Detour to success: photoswitching via indirect excitation",

abstract = "Photoswitchable molecules that undergo nanoscopic changes upon photoisomerisation can be harnessed to control macroscopic properties such as colour, solubility, shape, and motion of the systems they are incorporated into. These molecules find applications in various fields of chemistry, physics, biology, and materials science. Until recently, research efforts have focused on the design of efficient photoswitches responsive to low-energy (red or near-infrared) irradiation, which however may compromise other molecular properties such as thermal stability and robustness. Indirect isomerisation methods enable photoisomerisation with low-energy photons without altering the photoswitch core, and also open up new avenues in controlling the thermal switching mechanism. In this perspective, we present the state of the art of five indirect excitation methods: two-photon excitation, triplet sensitisation, photon upconversion, photoinduced electron transfer, and indirect thermal methods. Each impacts our understanding of the fundamental physicochemical properties of photochemical switches, and offers unique application prospects in biomedical technologies and beyond.",

author = "Kim Kuntze and Jussi Isokuortti and \{van der Wal\}, \{Jacob J.\} and Timo Laaksonen and Stefano Crespi and Durandin, \{Nikita A.\} and Arri Priimagi",

note = "Publisher Copyright: {\textcopyright} 2024 The Royal Society of Chemistry.",

year = "2024",

doi = "10.1039/d4sc02538e",

language = "English",

volume = "15",

journal = "Chemical Science",

issn = "2041-6520",

publisher = "Royal Society of Chemistry",

number = "30",

}

TY - JOUR

T1 - Detour to success

T2 - photoswitching via indirect excitation

AU - Kuntze, Kim

AU - Isokuortti, Jussi

AU - van der Wal, Jacob J.

AU - Laaksonen, Timo

AU - Crespi, Stefano

AU - Durandin, Nikita A.

AU - Priimagi, Arri

PY - 2024

Y1 - 2024

N2 - Photoswitchable molecules that undergo nanoscopic changes upon photoisomerisation can be harnessed to control macroscopic properties such as colour, solubility, shape, and motion of the systems they are incorporated into. These molecules find applications in various fields of chemistry, physics, biology, and materials science. Until recently, research efforts have focused on the design of efficient photoswitches responsive to low-energy (red or near-infrared) irradiation, which however may compromise other molecular properties such as thermal stability and robustness. Indirect isomerisation methods enable photoisomerisation with low-energy photons without altering the photoswitch core, and also open up new avenues in controlling the thermal switching mechanism. In this perspective, we present the state of the art of five indirect excitation methods: two-photon excitation, triplet sensitisation, photon upconversion, photoinduced electron transfer, and indirect thermal methods. Each impacts our understanding of the fundamental physicochemical properties of photochemical switches, and offers unique application prospects in biomedical technologies and beyond.

AB - Photoswitchable molecules that undergo nanoscopic changes upon photoisomerisation can be harnessed to control macroscopic properties such as colour, solubility, shape, and motion of the systems they are incorporated into. These molecules find applications in various fields of chemistry, physics, biology, and materials science. Until recently, research efforts have focused on the design of efficient photoswitches responsive to low-energy (red or near-infrared) irradiation, which however may compromise other molecular properties such as thermal stability and robustness. Indirect isomerisation methods enable photoisomerisation with low-energy photons without altering the photoswitch core, and also open up new avenues in controlling the thermal switching mechanism. In this perspective, we present the state of the art of five indirect excitation methods: two-photon excitation, triplet sensitisation, photon upconversion, photoinduced electron transfer, and indirect thermal methods. Each impacts our understanding of the fundamental physicochemical properties of photochemical switches, and offers unique application prospects in biomedical technologies and beyond.

U2 - 10.1039/d4sc02538e

DO - 10.1039/d4sc02538e

M3 - Article

AN - SCOPUS:85198139623

SN - 2041-6520

VL - 15

JO - Chemical Science

JF - Chemical Science

IS - 30

M1 - 11684

ER -

Detour to success: photoswitching via indirect excitation

Abstract

Funding

Publication forum classification

ASJC Scopus subject areas

Access to Document

Fingerprint

Cite this