| 799 - 799 |
Special Issue: Gasification: Fundamentals and application Preface
Xu GW, Li CZ, Sakanishi K |
| 800 - 804 |
Changes in char reactivity and structure during the gasification of a Victorian brown coal: Comparison between gasification in O-2 and CO2
Tay HL, Li CZ |
| 805 - 809 |
Experimental study on catalytic steam gasification of natural coke in a fluidized bed
Zhao CS, Lin LS, Pang KL, Xiang WG, Chen XP |
| 810 - 817 |
Fundamentals of coal topping gasification: Characterization of pyrolysis topping in a fluidized bed reactor
Xiong R, Dong L, Yu JA, Zhang XF, Jin L, Xu GW |
| 818 - 822 |
Experimental study of a commercial circulated fluidized bed coal gasifier
Ju FD, Chen HP, Yang HP, Wang XH, Zhang SH, Liu DC |
| 823 - 830 |
Thermodynamic analysis of coal pyrolysis to acetylene in hydrogen plasma reactor
Wu CN, Chen JQ, Cheng Y |
| 831 - 836 |
Artificial neural network model to predict slag viscosity over a broad range of temperatures and slag compositions
Duchesne MA, Macchi A, Lu DY, Hughes RW, McCalden D, Anthony EJ |
| 837 - 842 |
Influences of carbon structure on the reactivities of lignite char reacting with CO2 and NO
Zhu XL, Sheng CD |
| 843 - 847 |
Kinetic studies of char gasification by steam and CO2 in the presence of H-2 and CO
Huang ZM, Zhang JS, Zhao Y, Zhang H, Yue GX, Suda T, Narukawa M |
| 848 - 852 |
Gas evolution kinetics of two coal samples during rapid pyrolysis
Chen L, Zeng C, Guo X, Mao Y, Zhang Y, Zhang X, Li W, Long Y, Zhu H, Eiteneer B, Zamansky V |
| 853 - 858 |
Effect of cooling rate and alumina dissolution on the determination of temperature of critical viscosity of molten slag
Kim Y, Oh MS |
| 859 - 865 |
Bench-scale production of liquid fuel from woody biomass via gasification
Hanaoka T, Liu YY, Matsunaga K, Miyazawa T, Hirata S, Sakanishi K |
| 866 - 876 |
Automotive fuels from biomass via gasification
Zhang WN |
| 877 - 881 |
Evaluation of structural features of chars from pyrolysis of biomass of different particle sizes
Asadullah M, Zhang S, Li CZ |
| 882 - 888 |
Potential approaches to improve gasification of high water content biomass rich in cellulose in dual fluidized bed
Dong L, Xu GW, Suda T, Murakami T |
| 889 - 894 |
Low-temperature gasification of a woody biomass under a nickel-loaded brown coal char
Li LY, Morishita K, Mogi H, Yamasaki K, Takarada T |
| 895 - 902 |
Multi-stage biomass gasification in Internally Circulating Fluidized-bed Gasifier (ICFG): Test operation of animal-waste-derived biomass and parametric investigation at low temperature
Xiao XB, Le DD, Morishita K, Zhang SY, Li LY, Takarada T |
| 903 - 909 |
Effect of cellulose, lignin, alkali and alkaline earth metallic species on biomass pyrolysis and gasification
Lv DZ, Xu MH, Liu XW, Zhan ZH, Li ZY, Yao H |
| 910 - 914 |
Experimental study on sawdust air gasification in an entrained-flow reactor
Zhao YJ, Sun SZ, Zhou H, Sun R, Tian HM, Luan JY, Qian JA |
| 915 - 920 |
High density and high solids flux CFB risers for steam gasification of solids fuels
Bi XTT, Liu XH |
| 921 - 926 |
Characterizing the dynamic property of the vortex tail in a gas cyclone by wall pressure measurements
Gao CZ, Sun GG, Dong RQ, Fu SC |
| 927 - 933 |
Experimental validation of the gas-solid flow in the CFB riser
Wang XY, Liao LL, Fan BG, Jiang F, Xu XA, Wang SD, Xiao YH |
| 934 - 941 |
Modelling of an IGCC plant with carbon capture for 2020
Kunze C, Spliethoff H |
| 942 - 950 |
Pyrolysis of pine wood in a slowly heating fixed-bed reactor: Potassium carbonate versus calcium hydroxide as a catalyst
Wang ZY, Wang F, Cao JQ, Wang J |
| 951 - 957 |
Optimum operating conditions for a two-stage gasification process fueled by polypropylene by means of continuous reactor over ruthenium catalyst
Park Y, Namioka T, Sakamoto S, Min TJ, Roh SA, Yoshikawa K |
| 958 - 963 |
Experimental study on CO2 capture conditions of a fluidized bed limestone decomposition reactor
Wang Y, Lin SY, Suzuki Y |
| 964 - 981 |
In bed and downstream hot gas desulphurization during solid fuel gasification: A review
Meng XM, de Jong W, Pal R, Verkooijen AHM |
