Efficient syngas generation for electricity storage through carbon gasification assisted solid oxide co-electrolysis

Applied Energy

Volumn 173, Issue , 2016, Pages 52-58

  Lei, Libin ^a   Wang, Yao ^a,b   Fang, Shumin ^a   Ren, Cong ^a   Liu, Tong ^a,b   Chen, Fanglin ^a  

^a University of South Carolina   (United States)

^b WUHAN UNIVERSITY   (China)

Author keywords

Carbon gasification; Solid oxide electrolysis cell; Syngas production

Indexed keywords

ANODES; CARBON DIOXIDE; CHEMICAL PLANTS; ELECTRIC ENERGY STORAGE; ELECTRODES; ELECTROLYSIS; ELECTROLYTES; ELECTROLYTIC CELLS; FUELS; GAS GENERATORS; GASIFICATION; RENEWABLE ENERGY RESOURCES; SOLID OXIDE FUEL CELLS (SOFC); SYNTHESIS GAS;

CARBON GASIFICATION; ELECTRICITY STORAGES; ELECTROCHEMICAL REACTIONS; OXYGEN POTENTIAL GRADIENTS; RENEWABLE ENERGY SOURCE; SUSTAINABLE ENERGY SUPPLY; SYNGAS PRODUCTION; THERMODYNAMIC CALCULATIONS;

REGENERATIVE FUEL CELLS;

CARBON; CARBON DIOXIDE; CARBON MONOXIDE; ELECTRICAL POWER; ELECTRICITY; ELECTRODE; ELECTROKINESIS; ELECTROLYTE; ENERGY RESOURCE; EQUIPMENT; FUEL CELL; HIGH TEMPERATURE; PERFORMANCE ASSESSMENT; POWER GENERATION; RENEWABLE RESOURCE;

EID: 84962719950     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2016.03.116     Document Type: Article

References (42)

1. 2 co-electrolysis: an economic assessment. Energy Environ Sci 2010, 3:1382-1397.
2. 2O co-electrolysis in tubular solid oxide electrolysis cells. Energy Environ Sci 2014, 7:4018-4022.
3. Cinti G., Baldinelli A., Di Michele A., Desideri U. Integration of solid oxide electrolyzer and Fischer-Tropsch: a sustainable pathway for synthetic fuel. Appl Energy 2016, 162:308-320.
4. Xie Y., Xiao J., Liu D., Liu J., Yang C. Electrolysis of carbon dioxide in a solid oxide electrolyzer with silver-gadolinium-doped ceria cathode. J Electrochem Soc 2015, 162:F397-F402.
5. Tao G., Sridhar K., Chan C. Study of carbon dioxide electrolysis at electrode/electrolyte interface: Part I. Pt/YSZ interface. Solid State Ionics 2004, 175:615-619.
6. Stoots C.M., Hartvigsen J.J., O'Brien J.E., Herring J.S. Syngas production via high-temperature coelectrolysis of steam and carbon dioxide. J Fuel Cell Sci Technol 2009, 6:011014.
7. Kim-Lohsoontorn P., Bae J. Electrochemical performance of solid oxide electrolysis cell electrodes under high-temperature coelectrolysis of steam and carbon dioxide. J Power Sources 2011, 196:7161-7168.
8. Jensen S.H., Larsen P.H., Mogensen M. Hydrogen and synthetic fuel production from renewable energy sources. Int J Hydrogen Energy 2007, 32:3253-3257.
9. 2O: the basis for a renewable energy cycle. Energy Fuels 2009, 23:3089-3096.
10. Laguna-Bercero M. Recent advances in high temperature electrolysis using solid oxide fuel cells: a review. J Power Sources 2012, 203:4-16.
11. Martinez-Frias J., Pham A.-Q., Aceves S.M. A natural gas-assisted steam electrolyzer for high-efficiency production of hydrogen. Int J Hydrogen Energy 2003, 28:483-490.
12. 4 and CO assisted steam electrolysis. Topics Catal 2007, 46:380-385.
13. Wang W., Gorte R.J., Vohs J.M. Analysis of the performance of the electrodes in a natural gas assisted steam electrolysis cell. Chem Eng Sci 2008, 63:765-769.
14. Wang Y., Liu T., Fang S., Xiao G., Wang H., Chen F. A novel clean and effective syngas production system based on partial oxidation of methane assisted solid oxide co-electrolysis process. J Power Sources 2015, 277:261-267.
15. 2. Fuel 1998, 77:1831-1839.
16. 2 atmosphere and its kinetics since 1948: a brief review. Energy 2011, 36:12-40.
17. Gong Y., Huang K. Study of a renewable biomass fueled SOFC: the effect of catalysts. Int J Hydrogen Energy 2013, 38:16518-16523.
18. Kaklidis N., Kyriakou V., Garagounis I., Arenillas A., Menéndez J., Marnellos G., et al. Effect of carbon type on the performance of a direct or hybrid carbon solid oxide fuel cell. RSC Adv 2014, 4:18792-18800.
19. Lee A.C., Mitchell R.E., Gür T.M. Thermodynamic analysis of gasification-driven direct carbon fuel cells. J Power Sources 2009, 194:774-785.
20. Li S., Lee A.C., Mitchell R.E., Gür T.M. Direct carbon conversion in a helium fluidized bed fuel cell. Solid State Ionics 2008, 179:1549-1552.
21. Liu R., Zhao C., Li J., Zeng F., Wang S., Wen T., et al. A novel direct carbon fuel cell by approach of tubular solid oxide fuel cells. J Power Sources 2010, 195:480-482.
22. Tang Y., Liu J. Effect of anode and Boudouard reaction catalysts on the performance of direct carbon solid oxide fuel cells. Int J Hydrogen Energy 2010, 35:11188-11193.
23. Wu Y., Su C., Zhang C., Ran R., Shao Z. A new carbon fuel cell with high power output by integrating with in situ catalytic reverse Boudouard reaction. Electrochem Commun 2009, 11:1265-1268.
24. Xie Y., Cai W., Xiao J., Tang Y., Liu J., Liu M. Electrochemical gas-electricity cogeneration through direct carbon solid oxide fuel cells. J Power Sources 2015, 277:1-8.
25. Xie Y., Tang Y., Liu J. A verification of the reaction mechanism of direct carbon solid oxide fuel cells. J Solid State Electrochem 2013, 17:121-127.
26. Zhang L., Xiao J., Xie Y., Tang Y., Liu J., Liu M. Behavior of strontium-and magnesium-doped gallate electrolyte in direct carbon solid oxide fuel cells. J Alloys Compd. 2014, 608:272-277.
27. Gür T.M. Critical review of carbon conversion in "carbon fuel cells". Chem Rev 2013, 113:6179-6206.
28. Jiao Y., Tian W., Chen H., Shi H., Yang B., Li C., et al. In situ catalyzed Boudouard reaction of coal char for solid oxide-based carbon fuel cells with improved performance. Appl Energy 2015, 141:200-208.
29. Duan N.-Q., Tan Y., Yan D., Jia L., Chi B., Pu J., et al. Biomass carbon fueled tubular solid oxide fuel cells with molten antimony anode. Appl Energy 2016, 165:983-989.
30. Gopalan S., Ye G., Pal U.B. Regenerative, coal-based solid oxide fuel cell-electrolyzers. J Power Sources 2006, 162:74-80.
31. Alexander B.R., Mitchell R.E., Gür T.M. Steam-carbon fuel cell concept for cogeneration of hydrogen and electrical power. J Electrochem Soc 2011, 158:B505-B513.
32. Lee A.C., Mitchell R.E., Gür T.M. Feasibility of hydrogen production in a steam-carbon electrochemical cell. Solid State Ionics 2011, 192:607-610.
33. Ewan B.C., Adeniyi O.D. A demonstration of carbon-assisted water electrolysis. Energies 2013, 6:1657-1668.
34. Liu Q., Dong X., Xiao G., Zhao F., Chen F. A novel electrode material for symmetrical SOFCs. Adv Mater 2010, 22:5478-5482.
35. Chen Y., Zhang Y., Xiao G., Yang Z., Han M., Chen F. Sulfur-tolerant hierarchically porous ceramic anode-supported solid-oxide fuel cells with self-precipitated nanocatalyst. ChemElectroChem 2015, 2:672-678.
36. 6-δ as a regenerative anode for solid oxide fuel cells. J Power Sources 2011, 196:9148-9153.
37. 3 electrolyte. J Electrochem Soc 2011, 158:B455-B460.
38. 1.9 composite anodes for intermediate-temperature solid oxide fuel cells. J Electrochem Soc 2012, 159:B619-B626.
39. 1.9 nanoparticles. Electrochem Commun 2011, 13:711-713.
40. Ni M., Leung M.K., Leung D.Y. Energy and exergy analysis of hydrogen production by solid oxide steam electrolyzer plant. Int J Hydrogen Energy 2007, 32:4648-4660.
41. Zhang H., Lin G., Chen J. Evaluation and calculation on the efficiency of a water electrolysis system for hydrogen production. Int J Hydrogen Energy 2010, 35:10851-10858.
42. Luo Y., Shi Y., Li W., Ni M., Cai N. Elementary reaction modeling and experimental characterization of solid oxide fuel-assisted steam electrolysis cells. Int J Hydrogen Energy 2014, 39:10359-10373.