Photochromism and Dual‐Color Fluorescence in a Polyoxometalate–Benzospiropyran Molecular Switch

Abstract: Abstract:The photophysical properties of a Keggin-type polyoxometalate (POM) covalently bounded to a benzospiropyran (BSPR) unit have been investigated. These studies reveal that (i) both closed and open forms are emissive with distinct spectral features (λem, (closed form) = 530 nm, λem, (open form) = 670 nm); (ii) the fluorescence of the BSPR unit of the POM-based hybrid is considerably enhanced compared to BSPR reference compounds. While the fluorescence excitation energy of the BSPR reference compounds (37… Show more

“…Many studies on covalently functionalized POMS aimed to combine them with known chromophores. 14 Both organics and organometallic dyes were explored, such as benzospiropyran 15 , porphyrins, 9, 11b, 16 and Ru(II), 6c, 17 Ir(III) 18 and Re(I) 19 polypyridines complexes (Fig. 1).…”

Covalent hybrids based on Re(i) tricarbonyl complexes and polypyridine-functionalized polyoxometalate: synthesis, characterization and electronic properties

“…Many studies on covalently functionalized POMS aimed to combine them with known chromophores. 14 Both organics and organometallic dyes were explored, such as benzospiropyran 15 , porphyrins, 9, 11b, 16 and Ru(II), 6c, 17 Ir(III) 18 and Re(I) 19 polypyridines complexes (Fig. 1).…”

Covalent hybrids based on Re(i) tricarbonyl complexes and polypyridine-functionalized polyoxometalate: synthesis, characterization and electronic properties

“…POM molecules are a class of anionic metal‐oxide nanoclusters, which can achieve multiple stable metal‐centered redox states in a narrow potential range 196‐199 . Because of this multiredox behavior, POMs and their organic‐inorganic hybrid derivatives have become a new family of contenders for redox‐based resistive memory electronics 200‐206 …”

Recent advances in organic‐based materials for resistive memory applications

“…1,2 Optogenetics has revolutionized the eld involving the use of light to regulate the neuronal activity in biological systems as complex as live animals. [3][4][5] In particular, molecular photoswitches (e.g., diarylethene (DAE), azobenzene, and spiropyran), which undergo a reversible structure change upon light irradiation, have attracted great attention for biomedical applications, such as photocontrolled cell adhesion, 6 bioimaging, [7][8][9][10][11][12] and drug release. [13][14][15] For example, photoswitchable uorescence probes, whose uorescence can be modulated from a bright-to-dark or two color state through light control, have been developed for bioimaging with improved resolution and specicity.…”

“…[13][14][15] For example, photoswitchable uorescence probes, whose uorescence can be modulated from a bright-to-dark or two color state through light control, have been developed for bioimaging with improved resolution and specicity. [7][8][9][10][11][12] More recently, the employment of molecular photoswitches for controlling the action of therapeutics has enabled the emerging eld of photopharmacology. [16][17][18][19][20] These switching units allow for remote control of the function of bioactive molecules with light, and thus could reduce off-target activity and achieve high precision in treatment.…”

A photochromic upconversion nanoarchitecture: towards activatable bioimaging and dual NIR light-programmed singlet oxygen generation