| 41 |
Effect of surface properties of Ni-MgO-Al2O3 catalyst for simultaneous H2 production and CO2 utilization using dry reforming of coke oven gas
|
관리자 |
2022.08.15 |
21 |
| 40 |
Comparative Techno-economic analysis of methanol production via carbon dioxide reforming of landfill gas using a highly active and stable Nickel-based catalyst
|
관리자 |
2022.05.07 |
36 |
| 39 |
Oxygen defective bimodal porous Ni-CeO2-x-MgO-Al2O3 catalyst with multi-void spherical structure for CO2 reforming of CH4
|
관리자 |
2022.04.14 |
21 |
| 38 |
Improving the catalytic activity in dry reforming reaction by enhancing the oxygen storage capacity of Ce0.8Zr0.2O2 support through hydrogen heat-treatment
|
관리자 |
2022.04.14 |
11 |
| 37 |
Nanofiber structured oxygen defective CoFe2O4-x catalyst for the water-gas shift reaction in waste-to-hydrogen processes
|
관리자 |
2022.04.14 |
7 |
| 36 |
Optimization of nano-catalysts for application in compact reformers
|
관리자 |
2022.04.14 |
6 |
| 35 |
CO2 Reforming of CH4 Using Coke Oven Gas over Ni/MgO-Al2O3 Catalysts: Effect of the MgO:Al2O3 Ratio
|
관리자 |
2022.04.14 |
4 |
| 34 |
Deoxygenation of non-edible fatty acid for green diesel production: Effect of metal loading amount over Ni/MgO?Al2O3 on the catalytic performance and reaction pathway
|
관리자 |
2022.04.14 |
7 |
| 33 |
Sulfur-tolerant Pt/CeO2 catalyst with enhanced oxygen storage capacity by controlling the Pt content for the waste-to-hydrogen processes
|
관리자 |
2022.04.14 |
8 |
| 32 |
Highly sulfur tolerant and regenerable Pt/CeO2 catalyst for waste to energy
|
관리자 |
2022.04.14 |
6 |
| 31 |
Synthesis gas production from carbon dioxide reforming of methane over Ni-MgO catalyst: combined effects of titration rate during co-precipitation and CeO2 addition
|
관리자 |
2022.04.14 |
1 |
| 30 |
One-Pot synthesis of full-featured mesoporous Ni/alumina catalyst via spray pyrolysis-assisted EISA method for dry reforming of methane
|
관리자 |
2022.04.14 |
2 |
| 29 |
Customized Ni?MgO?Al2O3 catalyst for carbon dioxide reforming of coke oven gas: Optimization of preparation method and co-precipitation pH
|
관리자 |
2022.04.14 |
2 |
| 28 |
Comparison of the effects of the catalyst preparation method and CeO2 morphology on the catalytic activity of Pt/CeO2 catalysts for the water?gas shift reaction
|
관리자 |
2022.04.14 |
3 |
| 27 |
The role of additives (Ba, Zr, and Nd) on Ce/Cu/Al2O3 catalyst for water-gas shift reaction
|
관리자 |
2022.04.14 |
6 |
