CO<sub>2</sub>capture and conversion using Mg-MOF-74 prepared by a sonochemical method

Yang, Da-Ae; Cho, Hye-Young; Kim, Jun; Yang, Seung-Tae; Ahn, Wha‐Seung

doi:10.1039/c1ee02234b

Cited by 494 publications

(295 citation statements)

References 72 publications

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“…This research group has also compared the activity of selected MOF systems for the cycloaddition of CO 2 onto styrene oxide and among them, UIO-66-NH 2 MOF was found to be the most active, with 70% conversion in 1 h. [ 138 ] However, the reaction conditions remained at high pressure and temperature with the use of a toxic solvent. There are other examples showing the catalytic activity of MOFs (Ni(salphen)-MOF, [ 139 ] Mg-MOF-74, [ 140 ] ZIF-8 [ 141 ] and MIXMOF-5 [ 142 ] as catalysts for cycloaddition of CO 2 onto an epoxide. Compared with zeolite catalysts, the larger pores of MOF catalysts did promote cycloaddition of CO 2 on larger epoxides, but most of these systems were operated at high pressure (>5 atm) and temperature (100-140 °C), with quarternary ammonium ions as co-catalysts in some cases.…”

Section: Mofs As Catalystsmentioning

confidence: 99%

The Potential Applications of Nanoporous Materials for the Adsorption, Separation, and Catalytic Conversion of Carbon Dioxide

Sneddon

Greenaway

Yiu

2014

Advanced Energy Materials

177

104

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Carbon capture and storage (CCS) technologies aiming at tackling CO2 emission have attracted much attention from scientists of various backgrounds. Most CCS systems require an efficient adsorbent to remove CO2 from sources such as fossil fuels (pre‐combustion) or flue gas from power generation (post‐combustion). Research on developing efficient adsorbents with a substantial capacity, good stability and recyclability has grown rapidly in the past decade. Because of their high surface area, highly porous structure, and high stability, various nanoporous materials have been viewed as good candidates for this challenging task. Here, recent developments in several classes of nanoporous materials, such as zeolites, metal organic frameworks (MOFs), mesoporous silicas, carbon nanotubes, and organic cage frameworks, for CCS are examined and potential future directions for CCS technology are discussed. The main criteria for a sustainable CO2 adsorbent for industrial use are also rationalized. Moreover, catalytic transformations of CO2 to other chemical species using nanoporous catalysts and their potential for large scale carbon capture and utilization (CCU) processes are also discussed. Application of CCU technologies avoids any potential hazard associated with CO2 reservoirs and allows possible recovery of some running cost for CO2 capture by manufacturing valuable chemicals.

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Section: Mofs As Catalystsmentioning

confidence: 99%

The Potential Applications of Nanoporous Materials for the Adsorption, Separation, and Catalytic Conversion of Carbon Dioxide

Sneddon

Greenaway

Yiu

2014

Advanced Energy Materials

177

104

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“…The symbols are the isotherms from the GCMC simulations as predicted by the different models. 35 compared to the UFF isotherm at the lowpressure region. At the higher-pressure region (i.e., P = 0.1−1 kPa); however, both the model B and UFF predict a much higher loading than the experimental measurement.…”

Section: Journal Of Chemical Theory and Computationmentioning

confidence: 99%

Force-Field Development from Electronic Structure Calculations with Periodic Boundary Conditions: Applications to Gaseous Adsorption and Transport in Metal–Organic Frameworks

Lin

Lee

Gagliardi

et al. 2014

J. Chem. Theory Comput.

125

200

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We present a systematic and efficient methodology to derive accurate (nonpolarizable) force fields from periodic density functional theory (DFT) calculations for use in classical molecular simulations. The methodology requires reduced computation cost compared with other conventional ways. Moreover, the whole process is performed self-consistently in a fully periodic system. The force fields derived by using this methodology nicely predict the CO 2 and H 2 O adsorption isotherms inside Mg-MOF-74, and is transferable to Zn-MOF-74; by replacing the Mg-CO 2 interactions with the corresponding Zn-CO 2 interactions, we obtain an accurate prediction of the corresponding isotherm. We have applied this methodology to address the effect of water on the separation of flue gases in these materials. In general, the mixture isotherms of CO 2 and H 2 O calculated with these derived force fields show a significant reduction in CO 2 uptake with the existence of trace amounts of water vapor. The effect of water, however, is found to be quantitatively different between Mg-and Zn-MOF-74.

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“…Among the current MOF materials, MOF-74 is known to exhibit an exceptionally large surface area and higher CO 2 adsorption capacity under atmospheric conditions compared to the other MOFs [31,32]. [33].…”

Section: Introductionmentioning

confidence: 99%

Facile Synthesis of M-MOF-74 (M=Co, Ni, Zn) and its Application as an ElectroCatalyst for Electrochemical CO₂ Conversion and H₂ Production

Choi

Jung

Yoo

et al. 2017

Journal of Electrochemical Science and Technology

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Electrochemical conversion of CO 2 and production of H 2 were attempted on a three-dimensionally ordered, porous metal organic framework (MOF-74) in which transition metals (Co, Ni, and Zn) were impregnated. A lab-scale proton exchange membrane-based electrolyzer was fabricated and used for the reduction of CO 2 . Real-time gas chromatography enabled the instantaneous measurement of the amount of carbon monoxide and hydrogen produced. Comprehensive calculations, based on electrochemical measurements and gaseous product analysis, presented a time-dependent selectivity of the produced gases. M-MOF-74 samples with different central metals were successfully obtained because of the simple synthetic process. It was revealed that Co-and Ni-MOF-74 selectively produce hydrogen gas, while Zn-MOF-74 successfully generates a mixture of carbon monoxide and hydrogen. The results indicated that M-MOF-74 can be used as an electrocatalyst to selectively convert CO 2 into useful chemicals.

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CO₂capture and conversion using Mg-MOF-74 prepared by a sonochemical method

Cited by 494 publications

References 72 publications

The Potential Applications of Nanoporous Materials for the Adsorption, Separation, and Catalytic Conversion of Carbon Dioxide

The Potential Applications of Nanoporous Materials for the Adsorption, Separation, and Catalytic Conversion of Carbon Dioxide

Force-Field Development from Electronic Structure Calculations with Periodic Boundary Conditions: Applications to Gaseous Adsorption and Transport in Metal–Organic Frameworks

Facile Synthesis of M-MOF-74 (M=Co, Ni, Zn) and its Application as an ElectroCatalyst for Electrochemical CO₂ Conversion and H₂ Production

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CO2capture and conversion using Mg-MOF-74 prepared by a sonochemical method

Cited by 494 publications

References 72 publications

The Potential Applications of Nanoporous Materials for the Adsorption, Separation, and Catalytic Conversion of Carbon Dioxide

The Potential Applications of Nanoporous Materials for the Adsorption, Separation, and Catalytic Conversion of Carbon Dioxide

Force-Field Development from Electronic Structure Calculations with Periodic Boundary Conditions: Applications to Gaseous Adsorption and Transport in Metal–Organic Frameworks

Facile Synthesis of M-MOF-74 (M=Co, Ni, Zn) and its Application as an ElectroCatalyst for Electrochemical CO2 Conversion and H2 Production

Contact Info

Product

Resources

About

CO₂capture and conversion using Mg-MOF-74 prepared by a sonochemical method

Facile Synthesis of M-MOF-74 (M=Co, Ni, Zn) and its Application as an ElectroCatalyst for Electrochemical CO₂ Conversion and H₂ Production