Beyond Artificial Photosynthesis: Prospects on Photobiorefinery

Butburee, Teera; Chakthranont, Pongkarn; Phawa, Chaiyasit; Faungnawakij, Kajornsak

doi:10.1002/cctc.201901856

Cited by 54 publications

(34 citation statements)

References 212 publications

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“…In addition to lignocellulosic biomass, photocatalytic transformation of biomass-relevant alcohols is highly appealing for obtaining usable chemicals [48][49][50], which are pivotal [36]. Copyright 2017 American Chemi-cal Society.…”

Section: Photocatalytic Conversion Of Biomass-relevant Alcoholsmentioning

confidence: 99%

Valorization of Biomass-Derived Platform Molecules via Photoredox Sustainable Catalysis

Lin

Tang

et al. 2020

Trans. Tianjin Univ.

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The conversion of biomass into valuable chemicals has promise for application in biorefineries. Light-driven photoredox catalysis, with the typical features of green route and operation under mild conditions, is considered a promising strategy for renewable biomass or biomass-derived intermediates conversion into high-value-added chemical feedstocks. In this review, we strongly emphasize the recent advances in photocatalytic valorization of lignin model compounds and biomass-derived alcohols. We briefly summarize the advances in photocatalytic cleavage of the β-O-4 bond or C–C bond into usable chemicals in the lignin model. On the other hand, we clarify not only the hybrid system for cooperative biomass-relevant alcohols oxidation and hydrogen (H2) evolution but also the tunable accessibility to variation of the target products from the same alcohol reactant by catalyst design and optimization of reaction conditions. It is hoped that this review will inspire the rational design of photoredox catalysis-based systems toward efficient biomass-derived platform molecules valorization to obtain target-oriented valuable products.

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Section: Photocatalytic Conversion Of Biomass-relevant Alcoholsmentioning

confidence: 99%

Valorization of Biomass-Derived Platform Molecules via Photoredox Sustainable Catalysis

Lin

Tang

et al. 2020

Trans. Tianjin Univ.

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“…There has been growing interest in developing a “biorefinery” platform as opposed to the century-old petroleum refinery analogous for sustainable production of fuels and chemicals ( Ragauskas, et al., 2006 ) Unfortunately, two technologically advanced biorefinery platforms, including the thermochemical processes (such as combustion, pyrolysis, and gasification) and biological processes (such as enzymatic hydrolysis and micro-organisms fermentation) are facing setbacks due to carbon-intensive and expensive processes involved therein ( Huber, et al., 2006 ; Rubin, 2008 ). Among other emerging routes, solar-driven biomass photocatalysis (the so-called photo-biorefinery) is appealing to realize solar energy storage into chemical bonds with high energy density( Butburee, et al., 2020 ; Zhao, et al., 2021 ; Wu et al., 2020a , 2020b ; Wu, et al., 2017 ; Zhang et al., 2017a , 2017b ). As one of the most abundant biomass-based compounds, glucose has been utilized to produce various value-added chemicals like glucaric acid, gluconic acid, 5-hydroxymethylfurfural, and lactic acid( Liu et al., 2020a , 2020b ; Zhang and Huber, 2018 ).…”

Section: Introductionmentioning

confidence: 99%

Coproduction of hydrogen and lactic acid from glucose photocatalysis on band-engineered Zn1-xCdxS homojunction

Zhao

Yong

et al. 2021

iScience

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Summary Photocatalytic transformation of biomass into value-added chemicals coupled with co-production of hydrogen provides an explicit route to trap sunlight into the chemical bonds. Here, we demonstrate a rational design of Zn 1-x Cd x S solid solution homojunction photocatalyst with a pseudo-periodic cubic zinc blende (ZB) and hexagonal wurtzite (WZ) structure for efficient glucose conversion to simultaneously produce hydrogen and lactic acid. The optimized Zn 0.6 Cd 0.4 S catalyst consists of a twinning superlattice, has a tuned bandgap, and displays excellent efficiency with respect to hydrogen generation (690 ± 27.6 μmol·h −1 ·g cat. −1 ), glucose conversion (~90%), and lactic acid selectivity (~87%) without any co-catalyst under visible light irradiation. The periodic WZ/ZB phase in twinning superlattice facilitates better charge separation, while superoxide radical (⋅O 2 - ) and photogenerated holes drive the glucose transformation and water oxidation reactions, respectively. This work demonstrates that rational photocatalyst design could realize an efficient and concomitant production of hydrogen and value-added chemicals from glucose photocatalysis.

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“…Hydrogen production from photocatalytic water splitting (without biomass) is achievable, but at a very low quantum yield (~ 1.8%) due to a thermodynamic barrier and multi-electron transfer process [ 11 ], while quantum yield of photobiorefinary for H 2 production is achievable above 70% [ 12 ]. The photocatalytic reforming of biomass and biomass-derived substrates is energetically comparable to the overall water splitting process, except biomass replaces water as the electron and proton source, as shown in Fig.…”

Section: Introductionmentioning

confidence: 99%

Photocatalytic hydrogen evolution from biomass conversion

et al. 2021

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Biomass has incredible potential as an alternative to fossil fuels for energy production that is sustainable for the future of humanity. Hydrogen evolution from photocatalytic biomass conversion not only produces valuable carbon-free energy in the form of molecular hydrogen but also provides an avenue of production for industrially relevant biomass products. This photocatalytic conversion can be realized with efficient, sustainable reaction materials (biomass) and inexhaustible sunlight as the only energy inputs. Reported herein is a general strategy and mechanism for photocatalytic hydrogen evolution from biomass and biomass-derived substrates (including ethanol, glycerol, formic acid, glucose, and polysaccharides). Recent advancements in the synthesis and fundamental physical/mechanistic studies of novel photocatalysts for hydrogen evolution from biomass conversion are summarized. Also summarized are recent advancements in hydrogen evolution efficiency regarding biomass and biomass-derived substrates. Special emphasis is given to methods that utilize unprocessed biomass as a substrate or synthetic photocatalyst material, as the development of such will incur greater benefits towards a sustainable route for the evolution of hydrogen and production of chemical feedstocks.

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Beyond Artificial Photosynthesis: Prospects on Photobiorefinery

Cited by 54 publications

References 212 publications

Valorization of Biomass-Derived Platform Molecules via Photoredox Sustainable Catalysis

Valorization of Biomass-Derived Platform Molecules via Photoredox Sustainable Catalysis

Coproduction of hydrogen and lactic acid from glucose photocatalysis on band-engineered Zn1-xCdxS homojunction

Photocatalytic hydrogen evolution from biomass conversion

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