[1] 林善俊,李献宇,丁路,等. 内蒙煤焦CO2气化过程的结构演变特性[J]. 燃料化学学报,2016,44(12):1409-1415. LIN S J,LI X Y,DING L,et al. Structure evolution characteristics of Inner Mongolia coal char during CO2 gasification[J]. Journal of Fuel Chemistry and Technology,2016,44(12):1409-1415.
[2] 方梦祥,厉文榜,岑建孟,等. 煤催化气化技术的研究现状与展望[J]. 化工进展,2015,34(10):3656-3664. FANG M X,LI W B,CEN J M,et al. Progress and prospect of research on catalytic gasification of coal[J].Chemical Industry and Engineering Progress,2015,34(10):3656-3664.
[3] SAMAL S,RAY A K,BANDOPADHYAY A,et al. Proposal for resources,utilization and processes of red mud in India——a review[J]. International Journal of Mineral Processing,2013,118:43-55.
[4] YANIK J,EBALE S,KRUSE A,et al. Biomass gasification in supercritical water:Ⅱ. Effect of catalyst[J]. International Journal of Hydrogen Energy,2008,33(17):4520-4526.
[5] DUMAN G,UDDIN M A,YANIK J. Hydrogen production from algal biomass via steam gasification[J]. Bioresource Technology,2014,166:24-30.
[6] SONG J,YANG J K,LIANG S,et al. Red mud enhanced hydrogen production from pyrolysis of deep-dewatered sludge cakes conditioned with Fenton's reagent and red mud[J]. International Journal of Hydrogen Energy,2016,41(38):16762-16771.
[7] 李海宾,韩敏芳. 拜耳法赤泥催化煤焦-CO2气化反应特性[J]. 煤炭学报,2015,40(1):235-241. LI H B,HAN M F. Coal char-CO2 gasification reaction catalyzed by Bayer red mud[J]. Journal of China Coal Society,2015,40(1):235-241.
[8] LEE H S,NGUYENG-HUY C,PHAM T,et al. ZrO2-impregnated red mud as a novel catalyst for steam catalytic cracking of vacuum residue[J]. Fuel,2016,165:462-467.
[9] ZHU M H,WACHS I E. Iron-based catalysts for the high- temperature water-gas shift(HTWGS)reaction:a review[J]. Cheminform,2016,6:722-732.
[10] OHTSUKA Y,ASAMI K. Steam gasification of low-rank coals with a chlorine-free iron catalyst from ferric chloride[J]. Industrial & Engineering Chemistry Research,1991,30(8):1921-1926.
[11] POPA T,FAN M,ARGYLE M D,et al. H2 and COx generation from coal gasification catalyzed by a cost-effective iron catalyst[J]. Applied Catalysis A:General,2013,464/465(8):207-217.
[12] 汪合龙,刘永卓,郭庆杰,等. 褐煤煤焦"一步法"制天然气双功能催化剂Fe-Ni/ATP性能研究[J]. 燃料化学学报,2016,44(6):654-660. WANG H L,LIU Y Z,GUO Q J,et al. Catalytic performance of Fe-Ni/ATP bifunctional catalyst for natural gas making by one-step lignite char gasification[J]. Journal of Fuel Chemistry and Technology,2016,44(6):654-660.
[13] 齐学军,宋文武,刘亮,等. Fe对胜利褐煤焦结构和气化反应性能的影响[J]. 燃料化学学报,2015,43(5):554-559. QI X J,SONG W W,LIU L,et al. Effect of iron on Shengli brown coal char structure and its influence on gasification reactivity[J]. Journal of Fuel Chemistry and Technology,2015,43(5):554- 559.
[14] 郗艳荣,刘永卓,郭庆杰,等. 钙基复合载氧体的制备及反应性能[J]. 化工进展,2013,32(10):2446-2452. XI Y R,LIU Y Z,GUO Q J,et al. Preparation and characteristics of Ca-based compound oxygen carrier[J]. Chemical Industry and Engineering Progress,2013,32(10):2446-2452.
[15] JIANG M Q,HU J,WANG J,et al. Calcium-promoted catalytic activity of potassium carbonate for steam gasification of coal char:Effect of hydrothermal pretreatment[J]. Fuel,2013,109:14-20.
[16] DING X K,ZHANG Y F,ZHANG T K,et al. Effect of operational variables on the hydrogasification of inner mongolian lignite semicoke[J]. Energy & Fuels,2013,27(8):4589-4597.
[17] CHANG G Z,XIE J J,HUANG Y Q,et al. Gasification reactivity and pore structure development:effect of intermittent addition of steam on increasing reactivity of PKS biochar with CO2[J]. Energy & Fuels,2017,31:2887-2895.
[18] 许慎启,周志杰,代正华,等. 碱金属及灰分对煤焦碳微晶结构及气化反应特性的影响[J]. 高校化学工程学报,2010,24(1):64-70. XU S Q,ZHOU Z J,DAI Z H,et al. Effects of alkalimetal and ash on crystallite structure of coal char during pyrolysis and on gasification reactivity[J]. Journal of Chemical Engineering of Chinese Universities,2010,24(1):64-70.
[19] IVLEVAN P,MESSERER A,YANG X,et al. Raman microspectroscopic analysis of changes in the chemical structure and reactivity of soot in a diesel exhaust after treatment model system[J]. Environmental Science & Technology,2007,41(10):3702-3707.
[20] CHANG G Z,HUANG Y Q,XIE J J,et al. The lignin pyrolysis composition and pyrolysis products of palm kernel shell,wheat straw,and pine sawdust[J]. Energy Conversion & Management,2016,124:587-597.
[21] FERRARI A C,ROBERTSON J. Interpretation of Raman spectra of disordered and amorphous carbon[J]. Physical Review B:Condensed Matter,2000,61(20):14095-14107.
[22] TUINSTRA F,KOENIG J K. Raman spectrum of graphite[J]. The Journal of Chemical Physics,1970,53(3):1126-1130.
[23] MARQUES M,SUAREZ-RUIZ I,FLORES D,et al. Correlation between optical,chemical and micro-structural parameters of high-rank coals and graphite[J]. International Journal of Coal Geology,2009,77(3/4):377-382.
[24] 常国璋,黄艳琴,赖喜锐,等. 棕榈壳焦CO2气化过程中反应性及结构特性研究[J]. 燃料化学学报,2015,43(8):947-954. CHANG G Z,HUANG Y Q,LAI X R,et al. Experimental study on the structure and reactivity of palm kernel shell chars during CO2 gasification[J]. Journal of Fuel Chemistry and Technology,2015,43(8):947-954.
[25] LI X J,HAYASHI J I,LI C Z. FT-Raman spectroscopic study of the evolution of char structure during the pyrolysis of a Victorian brown coal[J]. Fuel,2006,85(12/13):1700-1707. |