Comparison of CO2 Photoreduction Systems: A Review

Wang, Weining; Soulis, Johnathon; Yang, Yu-Jun; Biswas, Pratim

doi:10.4209/aaqr.2013.09.0283

Cited by 136 publications

(70 citation statements)

References 110 publications

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“…Some of the strategies to address these issues are to tune the CO2 surface interaction with photocatalyst to increase reactant loading, and to alter CO2 molecule geometry via surface chemistry interactions for reactions to proceed and for products to be desorbed from reactive sites. From catalyst design and selection viewpoints, metal organic frameworks (MOF) have been considered as an excellent catalyst support system due to their high capacity to capture and reduce CO2 [7]. Zeolitic imidazolate frameworks (ZIF) are a subclass of MOFs featuring excellent CO2 uptake and simple fabrication.…”

Section: Introductionmentioning

confidence: 99%

Photoreduction of CO2 on ZIF-8/TiO2 nanocomposites in a gaseous photoreactor under pressure swing

Pipelzadeh

Rudolph

Hanson

et al. 2017

Applied Catalysis B: Environmental

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# Deceased in late 20152 Graphical abstract Research Highlights1. A new type of ZIF-8/TiO2 core-shell nanocomposite is designed to facilitate not only CO2 adsorption but also its subsequent photoreduction.2. Sequential fluctuation of reactor pressure plays an important role in promoting product desorption and increasing photocatalyst activity.3. This study highlights the significance of engineering variables including mass transfer and reactor design in photocatalytic reactions. Abstract:A new type of zeolitic imidazolate framework ZIF-8/TiO2 nanocomposites was developed for photocatalytic reduction of CO2 to CH4 and CO in a newly designed photoreactor under intentionally controlled pressure swing. The ZIF-8/TiO2 core-shell structure plays an important role in the adsorption of CO2 by ZIF-8 and subsequent in-situ photocatalytic reduction on TiO2. The introduction of pressure change in the reaction system facilitates the adsorption-desorption process of CO2 and reaction products, which 3 consequently led to improved photoreduction performance. This approach highlights the importance of mass transfer and reactor design for improved photoreduction.

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Section: Introductionmentioning

confidence: 99%

Photoreduction of CO2 on ZIF-8/TiO2 nanocomposites in a gaseous photoreactor under pressure swing

Pipelzadeh

Rudolph

Hanson

et al. 2017

Applied Catalysis B: Environmental

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“…One direction is to decouple water and carbon footprints or minimize their negative interactions, mostly through innovative energy production pathways, energy-saving and energy-harvesting water management processes. Wang et al [80 ] reviewed the fundamental sciences of nanomaterial-based photocatalytic reductions of converting CO 2 into hydrocarbon fuels, and identified potential technological pathways. Several strategies (e.g., semiconductor of specific electronic properties, nanoparticle design of novel morphologies) may potentially improve the conversion efficiency to an extent to which practical process engineering can be achieved at production scales.…”

Section: Clean Production Versus Energy-water Optimizationmentioning

confidence: 99%

Toward quantitative analysis of water-energy-urban-climate nexus for urban adaptation planning

Yang

Goodrich

2014

Current Opinion in Chemical Engineering

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“…The most interesting methods attempt the conversion of CO2 into other useful compounds, e.g. regenerated fuels or chemicals, through chemical reactions [2], catalytic [3] and photocatalytic processes [4].…”

Section: -Introductionmentioning

confidence: 99%

High Pressure Photoreduction of CO<sub>2</sub>: Effect of Catalyst Formulation, Hole Scavenger Addition and Operating Conditions

Bahadori¹,

Tripodi²,

Villa³

et al. 2018

Preprint

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The photoreduction of CO2 is an intriguing process, which allows the synthesis of fuels and chemicals. One of the limitations for CO2 photoreduction in the liquid phase is its low solubility in water. This point has been here addressed by designing a fully innovative concept of pressurized photoreactor, allowing operation up to 20 bar and applied to improve the productivity of this very challenging process. The photoreduction of CO2 in the liquid phase was performed using commercial TiO2 (Evonink P25), TiO2 obtained by flame spray pyrolysis (FSP) and gold doped P25 (0.2 wt% Au-P25) in the presence of Na2SO3 as hole scavenger (HS). The different reaction parameters (catalyst concentration, pH and amount of HS) have been addressed.The products in liquid phase were formic acid and formaldehyde. Moreover, for longer reaction time and with total consumption of HS, gas phase products formed (H2 and CO) after accumulation of significant amount of organic compounds in the liquid phase, due to their consecutive photoreforming. Enhanced CO2 solubility in water was achieved by adding a base (pH= 12-14).In basic environment, CO2 formed carbonates which further reduced to formaldehyde and formic acid and consequently formed CO/CO2+H2 in the gas phase through photoreforming. The

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Comparison of CO2 Photoreduction Systems: A Review

Cited by 136 publications

References 110 publications

Photoreduction of CO2 on ZIF-8/TiO2 nanocomposites in a gaseous photoreactor under pressure swing

Photoreduction of CO2 on ZIF-8/TiO2 nanocomposites in a gaseous photoreactor under pressure swing

Toward quantitative analysis of water-energy-urban-climate nexus for urban adaptation planning

High Pressure Photoreduction of CO<sub>2</sub>: Effect of Catalyst Formulation, Hole Scavenger Addition and Operating Conditions

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