Graphene–BODIPY as a photocatalyst in the photocatalytic–biocatalytic coupled system for solar fuel production from CO2

Yadav, Rajesh K.; Baeg, Jin‐Ook; Kumar, Abhishek; Kong, Ki−jeong; Oh, Gyu Hwan; Park, No‐Joong

doi:10.1039/c3ta14442a

Cited by 126 publications

(106 citation statements)

References 61 publications

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“…This Opinion focuses on tight electronic integration between enzymes and light-absorbers, employing four main strategies ( Figure 2): (i) non-specific interaction with light-absorbing components, (ii) specific covalent-linkage, (iii) immobilisation on porous semiconductor nanoparticles, and (iv) photoelectrodes. We will not include multicomponent, soup-like 'cascade' systems, as devised for light-driven, FDH-catalysed CO 2 reduction [40][41][42], which depend on regenerating freely diffusing components like NAD(P)H. It is important to note that, in vivo, enzymes do not operate in dilute solution, but tend to be concentrated together, for example on surfaces like membranes.…”

Section: Configurationsmentioning

confidence: 99%

Solar-driven proton and carbon dioxide reduction to fuels — lessons from metalloenzymes

Bachmeier

Armstrong

2015

Current Opinion in Chemical Biology

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Section: Configurationsmentioning

confidence: 99%

Solar-driven proton and carbon dioxide reduction to fuels — lessons from metalloenzymes

Bachmeier

Armstrong

2015

Current Opinion in Chemical Biology

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“…[7][8][9][10][11] The carboxyl groups can react with amine, secondary amine and other group. [12][13][14][15][16][17][18] The hydrogen of phenolic hydroxyl in GO can be substituted. [19][20][21][22] Hydroxyl group also can be initiated to grow polymer brushes form GO and reduced graphene oxide (RGO).…”

Section: Introductionmentioning

confidence: 99%

Chlorine-functionalized reduced graphene oxide for methylene blue removal

2015

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Chlorine-functionalized reduced graphene oxide was prepared by using graphene oxide and sulfuryl chloride as raw materials. It is firstly reported that the hydroxyl group in graphene oxide can be substituted by chlorine in sulfuryl chloride. The product has a wider pore size and average interlayer space, and its surface area can be easily utilized. The adsorption data indicate that the material has high adsorption capacity on methylene blue. The adsorption process follows a second-order rate and Bangham diffusion kinetic model. The adsorption of methylene blue preferably fitting the Langmuir adsorption isotherm suggests monolayer coverage of the adsorbed molecules. The adsorption capacity of the product for methylene blue is 221.4 mg g À1 at room temperature, which is significantly higher than those of reduced graphene oxide (80.0 mg g À1 ) and active carbon (46.7 mg g À1 ).

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“…The rhodium complex shuttles as an electron mediator between the graphene photocatalyst and NAD + , proving to be an efficient factor for regeneration of the NADH cofactor. Recently, a photocatalystbiocatalyst coupled system developed using graphene-based visible light active photocatalyst in a highly efficient manner, leading to high NADH regeneration (54.02% ± 0.61%), followed by its consumption in exclusive formic acid production (144.2 ± 1.8 µmol) from CO2 [33].…”

Section: Conversion Of Co2 To Formic Acid/formatementioning

confidence: 99%

Recent Progress and Novel Applications in Enzymatic Conversion of Carbon Dioxide

et al. 2017

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Turning carbon dioxide (CO 2 ) into fuels and chemicals using chemical, photochemical, electrochemical, and enzymatic methods could be used to recycle large quantities of carbon. The enzymatic method, which is inspired by cellular CO 2 metabolism, has attracted considerable attention for efficient CO 2 conversion due to improved selectivity and yields under mild reaction conditions. In this review, the research progress of green and potent enzymatic conversion of CO 2 into useful fuels and chemicals was discussed. Furthermore, applications of the enzymatic conversion of CO 2 to assist in CO 2 capture and sequestration were highlighted. A summary including the industrial applications, barriers, and some perspectives on the research and development of the enzymatic approach to convert CO 2 were introduced.

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Graphene–BODIPY as a photocatalyst in the photocatalytic–biocatalytic coupled system for solar fuel production from CO2

Cited by 126 publications

References 61 publications

Solar-driven proton and carbon dioxide reduction to fuels — lessons from metalloenzymes

Solar-driven proton and carbon dioxide reduction to fuels — lessons from metalloenzymes

Chlorine-functionalized reduced graphene oxide for methylene blue removal

Recent Progress and Novel Applications in Enzymatic Conversion of Carbon Dioxide

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