Oligoethylene Glycol Side Chains Increase Charge Generation in Organic Semiconductor Nanoparticles for Enhanced Photocatalytic Hydrogen Evolution.
Jan KoscoSoranyel Gonzalez CarreroCalvyn T HowellsWeimin ZhangMaximilian MoserRajendar SheelamanthulaLingyun ZhaoBenjamin WillnerTania Cecilia HidalgoHendrik FaberBalaji PurushothamanMichael SachsHyojung ChaRachid SougratThomas D AnthopoulosSahika InalJames R DurrantIain McCullochPublished in: Advanced materials (Deerfield Beach, Fla.) (2021)
Organic semiconductor nanoparticles (NPs) composed of an electron donor/acceptor (D/A) semiconductor blend have recently emerged as an efficient class of hydrogen-evolution photocatalysts. It is demonstrated that using conjugated polymers functionalized with (oligo)ethylene glycol side chains in NP photocatalysts can greatly enhance their H2 -evolution efficiency compared to their nonglycolated analogues. The strategy is broadly applicable to a range of structurally diverse conjugated polymers. Transient spectroscopic studies show that glycolation facilitates charge generation even in the absence of a D/A heterojunction, and further suppresses both geminate and nongeminate charge recombination in D/A NPs. This results in a high yield of photogenerated charges with lifetimes long enough to efficiently drive ascorbic acid oxidation, which is correlated with greatly enhanced H2 -evolution rates in the glycolated NPs. Glycolation increases the relative permittivity of the semiconductors and facilitates water uptake. Together, these effects may increase the high-frequency relative permittivity inside the NPs sufficiently, to cause the observed suppression of exciton and charge recombination responsible for the high photocatalytic activities of the glycolated NPs.
Keyphrases
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- visible light
- high frequency
- oxide nanoparticles
- room temperature
- transcranial magnetic stimulation
- molecular docking
- dna damage
- dna repair
- photodynamic therapy
- hydrogen peroxide
- gold nanoparticles
- highly efficient
- water soluble
- high resolution
- blood brain barrier
- subarachnoid hemorrhage
- molecular dynamics simulations
- structure activity relationship