Artificial photosynthesis by light absorption, charge separation, and multielectron catalysis

Đokić, Miloš; Soo, Han Sen

doi:10.1039/c8cc02156b

Cited by 52 publications

(24 citation statements)

References 152 publications

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“…As part of the sustainable energy and green chemistry efforts in our team, we have recently been developing multi-dimensional lead and tin halide perovskites for light absorption and emission purposes (Koh et al., 2016, Thirumal et al., 2017) and creating innovative energy solutions based on artificial photosynthesis (Dokic and Soo, 2018, Gazi et al., 2017, Hong et al., 2019, Lim et al., 2018, Ng et al., 2018). Simultaneously, we have also been developing more eco-friendly, essentially solvent-free, mechanochemical approaches for the synthesis, functionalization, and transformation of main group compounds (Shi et al., 2016, Sim et al., 2017, Sim et al., 2018) and complexes (Geciauskaite and Garcia, 2017, Tan and Garcia, 2019, Wang et al., 2016, Wang et al., 2017).…”

Section: Introductionmentioning

confidence: 99%

Completely Solvent-free Protocols to Access Phase-Pure, Metastable Metal Halide Perovskites and Functional Photodetectors from the Precursor Salts

et al. 2019

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Mechanochemistry is a green, solid-state, re-emerging synthetic technique that can rapidly form complex molecules and materials without exogenous heat or solvent(s). Herein, we report the application of solvent-free mechanochemical ball milling for the synthesis of metal halide perovskites, to overcome problems with solution-based syntheses. We prepared phase-pure, air-sensitive CsSnX 3 (X = I, Br, Cl) and its mixed halide perovskites by mechanochemistry for the first time by reactions between cesium and tin(II) halides. Notably, we report the sole examples where metastable, high-temperature phases like cubic CsSnCl 3 , cubic CsPbI 3 , and trigonal FAPbI 3 were accessible at ambient temperatures and pressures without post-synthetic processing. The perovskites can be prepared up to ''kilogram scales.'' Lead-free, all-inorganic photodetector devices were fabricated using the mechanosynthesized CsSnBr 1.5 Cl 1.5 under solvent-free conditions and showed 10-fold differences between on-off currents. We highlight an essentially solvent-free, general approach to synthesize metastable compounds and fabricate photodetectors from commercially available precursors.

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Section: Introductionmentioning

confidence: 99%

Completely Solvent-free Protocols to Access Phase-Pure, Metastable Metal Halide Perovskites and Functional Photodetectors from the Precursor Salts

et al. 2019

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“…The exploitation of solar energy in the production of fuels and chemicals has taken on greater urgency lately due to the increasingly palpable environmental and economic effects of global climate change. To address this challenge, several groups, including ours [1][2][3][4][5][6][7][8][9]. have been inspired by the effectiveness of natural photosynthesis in capturing sunlight and coupling the separated charges for multielectron redox catalysis.…”

Section: Introductionmentioning

confidence: 99%

“…The two chromophores, chlorophylls P680 and P700, are organized so that electrons flow from P680 to P700 with high fidelity by interfacing with both thermodynamically and kinetically favorable intermediates. This essentially creates a "molecular photodiode" for effective light absorption and charge separation, allowing P680 to build up four holes to oxidize water, while P700 acquires two electrons to reduce NADP + [9].…”

Section: Introductionmentioning

confidence: 99%

“…Z. Li and his co-workers have also used metal organic frameworks (MOFs) [37,38] and ZnIn 2 S 4 [39] in the oxidation of amines to imines, which are important building blocks for the synthesis of fine chemicals. In the same vein, our team has been developing alternative approaches to harness sunlight in the production of solar chemicals and fuels, while using exclusively earth abundant elements [9]. We have developed molecular complexes and metal oxide semiconductors as chromophores [40,41], molecular Ni electrocatalysts capable of H 2 evolution from seawater [42], and molecular V photocatalysts that mediate C-C bond cleavage in biomass lignin model compounds, with the intention of integrating them into one unit for solar chemicals production [9,43,44].…”

Section: Introductionmentioning

confidence: 99%

“…In the same vein, our team has been developing alternative approaches to harness sunlight in the production of solar chemicals and fuels, while using exclusively earth abundant elements [9]. We have developed molecular complexes and metal oxide semiconductors as chromophores [40,41], molecular Ni electrocatalysts capable of H 2 evolution from seawater [42], and molecular V photocatalysts that mediate C-C bond cleavage in biomass lignin model compounds, with the intention of integrating them into one unit for solar chemicals production [9,43,44]. Some candidates that have emerged for solar to chemical energy conversion are Bi-based materials, due to their efficient photocatalytic performance, high stability, low cost, and modest toxicity [45].…”

Section: Introductionmentioning

confidence: 99%

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Mesoporous SiO2/BiVO4/CuO nanospheres for Z-scheme, visible light aerobic C–N coupling and dehydrogenation

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Atomic‐Level Charge Separation Strategies in Semiconductor‐Based Photocatalysts

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Semiconductor‐based photocatalysis as a productive technology furnishes a prospective solution to environmental and renewable energy issues, but its efficiency greatly relies on the effective bulk and surface separation of photoexcited charge carriers. Exploitation of atomic‐level strategies allows in‐depth understanding on the related mechanisms and enables bottom‐up precise design of photocatalysts, significantly enhancing photocatalytic activity. Herein, the advances on atomic‐level charge separation strategies toward developing robust photocatalysts are highlighted, elucidating the fundamentals of charge separation and transfer processes and advanced probing techniques. The atomic‐level bulk charge separation strategies, embodied by regulation of charge movement pathway and migration dynamic, boil down to shortening the charge diffusion distance to the atomic‐scale, establishing atomic‐level charge transfer channels, and enhancing the charge separation driving force. Meanwhile, regulating the in‐plane surface structure and spatial surface structure are summarized as atomic‐level surface charge separation strategies. Moreover, collaborative strategies for simultaneous manipulation of bulk and surface photocharges are also introduced. Finally, the existing challenges and future prospects for fabrication of state‐of‐the‐art photocatalysts are discussed on the basis of a thorough comprehension of atomic‐level charge separation strategies.

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Artificial photosynthesis by light absorption, charge separation, and multielectron catalysis

Cited by 52 publications

References 152 publications

Completely Solvent-free Protocols to Access Phase-Pure, Metastable Metal Halide Perovskites and Functional Photodetectors from the Precursor Salts

Completely Solvent-free Protocols to Access Phase-Pure, Metastable Metal Halide Perovskites and Functional Photodetectors from the Precursor Salts

Mesoporous SiO2/BiVO4/CuO nanospheres for Z-scheme, visible light aerobic C–N coupling and dehydrogenation

Atomic‐Level Charge Separation Strategies in Semiconductor‐Based Photocatalysts

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