Lateral Charge Migration in 1D Semiconductor-Metal Hybrid Photocatalytic Systems

Micheel, Mathias; Dong, Kaituo; Amirav, Lilac; Wächtler, Maria

doi:10.26434/chemrxiv-2023-rwtns

Cited by 2 publications

(1 citation statement)

References 40 publications

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“…To fully harness the potential of those lowdimensional biohybrid systems, it's essential to engineer semiconductors and bacteria based on detailed, systemic, and quantitative insights that enhance energy conversion e ciencies 16 . Although research has begun to explore the variables in uencing the effectiveness of semiconductor biohybrids, a comprehensive assessment of nanomaterial dimensions and electron transfer mechanisms is still in its infancy 17,18 . Current studies have primarily focused on photoelectron transfer mechanisms in biohybrids with extracellular or periplasmic nanomaterial localization [19][20][21] , where electrons must traverse cellular membranes-an energy-consuming bottleneck 22 .…”

Section: Introductionmentioning

confidence: 99%

Enhancing Solar-to-Chemical Conversion through Tailoring Dimensions of Semiconductors in Biohybrid Systems

Guo*,

Kong*,

Cheng

et al. 2024

Preprint

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Integrating light-harvesting semiconductor materials with biocatalysts offers a promising approach for solar-power production of fuels and fine chemicals. Despite significant advances, the influence of materials’ dimensions on energy utilization efficiency and the involved photoelectron transfer pathways remains largely to be explored. Here, we investigated the effect of dimensionality on the energy conversion efficiency in semiconductor nanomaterial-based biohybrid systems. We found that the intracellularly localized 2D nanoplatelets, particularly with core-crown heterostructures, were more efficient in supplying energy for microbial chemical production than the lower-dimensional nanomaterials. The biohybrids possessing the 2D nanoplatelets exhibited a 2.69-fold increase in 2,3-butanediol (BDO) production yield and achieved 2.35% solar-to-chemical conversion efficiency. Based on metabolomic and transcriptomic analyses, we identified a novel thiamine pyrophosphate (TPP)-mediated pathway of energy generation from photoexcited electrons. Furthermore, the addition of TPP enhanced the BDO production of the biohybrids under illumination. Our results demonstrate the potential to increase the solar-to-chemical conversion efficiency of semiconductor biohybrids by tailoring the dimension of semiconductor nanomaterials and engineering the intracellular electron transfer and energy generation pathways.

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Section: Introductionmentioning

confidence: 99%

Enhancing Solar-to-Chemical Conversion through Tailoring Dimensions of Semiconductors in Biohybrid Systems

Guo*,

Kong*,

Cheng

et al. 2024

Preprint

View full text Add to dashboard Cite

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Lateral charge migration in 1D semiconductor–metal hybrid photocatalytic systems

Micheel

Dong

Amirav

et al. 2023

The Journal of Chemical Physics

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Colloidal nanorods based on CdS or CdSe, functionalized with metal particles, have proven to be efficient catalysts for light-driven hydrogen evolution. Seeded CdSe@CdS nanorods have shown increasing performance with increasing rod length. This observation was rationalized by the increasing lifetime of the separated charges, as a large distance between holes localized in the CdSe seed and electrons localized at the metal tip decreases their recombination rate. However, the impact of nanorod length on the electron-to-tip localization efficiency or pathway remained an open question. Therefore, we investigated the photo-induced electron transfer to the metal in a series of Ni-tipped CdSe@CdS nanorods with varying length. We find that the transfer processes occurring from the region close to the semiconductor–metal interface, the rod region, and the CdSe seed region depend in different ways on the rods’ length. The rate of the fastest process from excitonic states generated directly at the interface is independent of the rod length, but the relative amplitude decreases with increasing rod length, as the weight of the interface region is decreasing. The transfer of electrons to the metal tip from excitons generated in the CdS rod region depends strongly on the length of the nanorods, which indicates an electron transport-limited process, i.e., electron diffusion toward the interface region, followed by fast interface crossing. The transfer originating from the CdSe excitonic states again shows no significant length dependence in its time constant, as it is probably limited by the rate of overcoming the shallow confinement in the CdSe seed.

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Lateral Charge Migration in 1D Semiconductor-Metal Hybrid Photocatalytic Systems

Cited by 2 publications

References 40 publications

Enhancing Solar-to-Chemical Conversion through Tailoring Dimensions of Semiconductors in Biohybrid Systems

Enhancing Solar-to-Chemical Conversion through Tailoring Dimensions of Semiconductors in Biohybrid Systems

Lateral charge migration in 1D semiconductor–metal hybrid photocatalytic systems

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