Photoinduced electron Transfer (PeT) between the photoactive cage and the encapsulated Fluorescein, and Photoinduced Energy Transfer (PET) from the cage to the encapsulated
Conclusions Photoinduced electron transfer (PET) utilizing alpha-amino radicals was shown to be applicable to problem solving in organic synthesis. Alpha oxo- and alpha thio-radicals are also
Introduction Photoinduced electron transfer (PeT) is a fundamental electron transfer mechanism, which is widely employed in the design of fluorescent probes. 1 A typical fluorescent PeT probe consists of
Photoinduced electron transfer (PET) is one of the most important mechanisms for developing fluorescent probes and biosensors for antioxidants. Quantitative prediction of
This review presents recent progress in organic, luminescent lanthanide-based photo-responsive materials, highlighting their design strategies, classification by photochromic mechanisms, and
Meanwhile, the photothermal property of PBNPs was activated by the phosphorescent emission of OC through photoinduced energy transfer. As a proof of concept,
Abstract Research on noble metal nanoclusters (MNCs) (elements with filled electron d-bands) is progressing forward because of the extensive and extraordinary chemical, optical, and physical
New Anderson‐Based Polyoxometalate Covalent Organic Frameworks as Electrodes for Energy Storage Boosted Through Keto‐Enol Tautomerization Iron (II)‐Catalyzed Aerobic Biomimetic
Abstract:Fast photochromic and fluorescent switchable organohydrogels based on photoinduced electron transfer for display and storage
Photoinduced electron transfer (PeT) between the photoactive cage and the encapsulated Fluorescein and photoinduced energy transfer (PET) from the cage to encapsulated Rose
Request PDF | On Oct 1, 2023, Na Chen and others published Fast photochromic and fluorescent switchable organohydrogels based on photoinduced electron transfer for display and storage |
We show the application of a new type of spectator ligand in a bridged Ru−Pt photocatalyst. In contrast to recently used peripheral ligands, those spectators enable
The fluorescent LCP was obtained by the copolymerization of one LC monomer (CH) and another fluorescent monomer containing α-cyanostilbene units (TP), designated as PCHTP, and it can
Request PDF | On Apr 1, 2025, Hongzhi Liang and others published Development of Fluorescent-Photothermal Probe Based on Photoinduced Energy Transfer: A Dual-Readout Immunosensor
Under the condition that viologen molecules serve as suitable electron acceptors and interact with ZnO nanoparticles, a photoinduced electron transfer reaction can be
In general, there are several main detection mechanisms based on fluorescence sensing, 1 fluorescence resonance energy transfer (FRET) [36], 2 intramolecular charge transfer (ICT), 3
In this Review, various classes of molecular photoswitches triggered with visible light are reported together with their applications in phototriggered smart materials – polymers,
Photoinduced electron-transfer chemistry of the bielectrophoric N-phthaloyl derivatives of the amino acids tyrosine, histidine and tryptophan
The development of advanced optical probes for point-of-care testing holds great importance in the field of diagnostic technologies. This study focused on the synthesis of a
Development of Fluorescent-Photothermal Probe Based on Photoinduced Energy Transfer: A Dual-Readout Immunosensor for the Detection of Illegal Additive Hongzhi Liang 1
The photoinduced spin crossover switched the energy transfer from the fluorophore to the Fe II ion, resulting in fluorescence modulation. The presented results provide
Spectroscopic techniques that confirm energy transfer from the fluorescent cage to dyes (e.g., NiR, R700, and R800) are efficient, which induce the red shift of fluorescence. On the other hand, ultrafast
Entangled Azobenzene‐Containing Polymers with Photoinduced Reversible Solid‐to‐Liquid Transitions for Healable and Reprocessable Photoactuators
In this Review, various classes of molecular photoswitches triggered with visible light are reported together with their applications in phototriggered smart materials – polymers, hydrogels, surfaces, porous
The invention discloses a photoinduced energy storage simulated plant, which is composed of simulated plant leaves and a fixed plate, and the simulated plant leaves include 2-10% of long
Photo-induced energy storage luminous powder is a photo-induced energy storage luminous powder that stores light energy after being irradiated by natural light, daylight, ultraviolet light,
ConspectusPhotoinduced electron transfer (PET) plays relevant roles in many areas of chemistry, including charge separation processes in photovoltaics, natural and artificial photosynthesis, and
In addition, ultrafast photoinduced electron transfer (PET) can be practised using MNCs under various circumstances. Herein, we have focused on the energy harvesting phenomena of Au-, Ag-, and Cu-based
Herein, we report a host–guest approach by using a tetraphenylethene-based octacationic cage and fluorescent dyes to construct artificial photofunctional systems with energy and electron transfer functions.
The development of advanced optical probes for point-of-care testing holds great importance in the field of diagnostic technologies. This study focused on the synthesis of a probe featuring
Nowadays, MNCs are very effectively used as energy donors and acceptors under suitable conditions and hence act as energy harvesters in solar cells, semiconductors, and biomarkers.
On the other hand, ultrafast photoinduced electron transfer from dyes (e.g., ICG, AG, and AV) to the fluorescent cage can induce fluorescence quenching. This study provides an insight into the construction of artificial photofunctional systems with energy and electron transfer functions via a host–guest approach in solution.
Spectroscopic techniques that confirm energy transfer from the fluorescent cage to dyes (e.g., NiR, R700, and R800) are efficient, which induce the red shift of fluorescence. On the other hand, ultrafast photoinduced electron transfer from dyes (e.g., ICG, AG, and AV) to the fluorescent cage can induce fluorescence quenching.
In addition, ultrafast photoinduced electron transfer (PET) can be practised using MNCs under various circumstances. Herein, we have focused on the energy harvesting phenomena of Au-, Ag-, and Cu-based MNCs and elaborated on different ways to apply them.
Cite this: ACS Appl. Mater. Interfaces 2021, 13, 14, 16837–16845 Artificial photofunctional systems with energy and electron transfer functions, inspired from photosynthesis in nature, have been developed for many promising applications including solar cell, biolabeling, photoelectric materials, and photodriven catalysis.
