| Formatted contents note |
Section 1: General Overview <br/>1. Carbon dioxide utilization: Greening both the energy and chemical industry. An overview, Michele Aresta<br/><br/>Section 2: Simultaneous Utilization <br/>2. Catalysis in the simultaneous utilization of greenhouse gases, Zhen Yan et al.<br/>3. Novel highly active reforming catalyst system and production of pure H2 from CH4 and CO2 with Pd-Ag membrane reactor, Linsheng Wang, Kazuhisa Murata, and Megumu Inaba<br/>4. Dry reforming of ethane on trimetallic perovskites LaCoxFe1-xO3. Characterisations and reactivity, G. Rodriguez et al.<br/>5. Combined Carbon Dioxide and Steam Reforming with Methane in Low Temperature Plasmas, Korada Supat et al.<br/>6. Influence of Electrode Configuration on Direct Methane Conversion with CO2 asa Co-reactant Using Dielectric-barrier Discharges, Yue-ping Zhang et al.<br/>7. Effect of H2S on the reaction of CH4 with CO2 over titania-supported noble metal catalysts, Andras Erdohelyi, Tamas Szailer, and Eva Novak<br/><br/>Section 3: Organic Synthesis with CO2 as a Reactant <br/>8. A Novel Route for Carbon Dixode Cyloaddition to Propylene Carbonate, Wei Wei, Tong Wei, and Yuhan Sun<br/>9. Catalytic Behavior of Calcium Oxide for Synthesis of Dimethyl Carbonate from Propylene Carbonate and Methanol near Room Temperature, Tong Wei et al.<br/>10. Catalytic Esterification of Carbon Dioxide and Methanol for the Preparation of Dimethyl Carbonate, Fa-hai Cao et al.<br/>11. Electrochemical Reduction of CO2 on Cu Electrode in Methanol at Low Temperature, Satoshi Kaneco et al.<br/>12. CO2 hydrogenation over copper-based hybrid catalysts for the synthesis of oxygenates, Son-ki Ihm et al.<br/>13. Methanol Synthesis from H2/CO/CO2 over CNTs-Promoted Cu-ZnO-Al2O3 Catalyst:CH3OH Synthesis over CuiZnjAlk-Ox/CNTs, Hong-Bin Zhang et al.<br/><br/>Section 4: Biochemical Fixation of CO2 <br/>14. Enzymatic Conversion of Carbon Dioxide to Methanol by Dehydrogenases Encapsulated in Sol-gel Matrix, Zhongyi Jiang et al.<br/>15. Towards solar energy conversion into fuels: Design and synthesis of Ruthenium-Manganese Supramolecular complexes to mimic the function of photosystem II., Licheng Sun et al.<br/><br/>Section 5: Methane Valorization <br/>16. Catalytic stability of Ni catalyst for partial oxidation of methane to syngas, Zhenhua Li et al.<br/>17. Benzene and methane partial oxidation in new iron zeolite topologies, Peter-Paul H. J. M. Knops-Gerrits<br/>18. Direct partial oxidation of methane to methanol in a specially design reactor, Qijian Zhang et al.<br/><br/>Section 6: Conversion of Methane and Other Greenhouse Gases via Plasmas or Microwave Heating <br/>19. Plasma catalytic hybrid reforming of methane, Thomas Hammer, Thomas Kappes, and Wolfgang Schiene<br/>20. Methane coupling and reforming using non-equilibrium pulsed discharge at room temperature: Catalyst-pulsed discharge combined system, S. Kado et al.<br/>21. Evaluation of a high-energy transform efficiency pulse power supply for methane plasma conversion, Mamoru Okumoto et al.<br/>22. Factors affecting the catalytic activation of methane via microwave heating, L. Daniel Conde and Steven L. Suib<br/>23. Decomposition of CF4 by microwave heating: a potential way to decrease greenhouse gas emissions, Franz-Josef Spiess et al.<br/><br/>Section 7: Application of Supercritical CO2 <br/>24. Application of high-pressure phase equilibria to the selective oxidation of alcohols over supported platinum catalysts in "supercritical" carbon dioxide, Roger Glaser et al.<br/><br/>Section 8: Methane Combustion <br/>25. Catalytic oxidation of methane over Co/Mn mixed oxides, W.-B. Li, Y. Lin, and Y. Zhang<br/>26. Supported Pd catalyst for high-temperature methane combustion: Examining the combustion synthesis preparation method, M. A. Fraga, M. C. Greca, and L. G. Appel<br/> |
