1、Xiaomin Gong, Ze Wang, Shuang Deng, Songgeng Li, Wenli Song and Weigang Lin. Impact of the Temperature, Pressure, and Particle Size on Tar Composition from Pyrolysis of Three Ranks of Chinese Coals. Energy and Fuels. 2014, 28 (8), pp 4942–4948.2、Shuang Deng, Yingjie Shi, Yu Liu, Chen Zhang, Xiangfeng Wang, Qing Cao, Songgeng Li, Fan Zhang. Emission characteristics of Cd, Pb and Mn from coal combustion: Field study at coal-fired power plants in China. Fuel Processing Technology. 2014, 126:469-475.
3、Zhan Shu, Junwu Wang, Chuigang Fan, and Songgeng Li. Multifluid Modeling of Mixing and Segregation of Binary Gas–Solid Flow in a Downer Reactor for Coal Pyrolysis. Ind. Eng. Chem. Res, 2014, 53(23), pp 9915–9924.
4、Zhan Shu, Guo Peng, Junwu Wang, Nan Zhang, Songgeng Li, and Weigang Lin. Comparative CFD Analysis of Heterogeneous Gas–Solid Flow in a Countercurrent Downer Reactor. Ind. Eng. Chem. Res, 2014,53(8), pp 3378–3384.
5、Yuzhe Li, Chuigan Fan, Wenli Song. Pyrolysis-bridged hybrid power systems and their application for thermal power plants. Energy Fuels, 2014,28(10), pp 6531-6539.
6、Ping Feng, Lifang Hao, Chaofei Huo, Ze Wang, Weigang Lin, Wenli Song. Rheological behavior of coal bio-oil slurries. Energy, 66 (2014) 744-749.
7、Dan Dang, Ze Wang, Anders Thygesen, Caixia Wang, Wei Zhou, Jianmin Xing and Weigang Lin. Bio-oil Treated by Cultivation of Saccharomyces cerevisiae. BioResources. 2014,9(2),pp:2727-2738.
8、Mo Zheng, Xiaoxia Li, Jian Liu, Ze Wang, Xiaomin Gong, Li Guo and Wenli Song. Pyrolysis of Liulin Coal Simulated by GPU-Based ReaxFF MD with Cheminformatics Analysis. Energy Fuels 2014, 28, 522−53.
9、方晓晴,范垂钢,都林,宋文立,林伟刚,李松庚. 煤焦直接还原脱除烟道气氮氧化物. 化工学报. 2014年第65卷第6期,pp:2249-2255.
10、梅磊,贺露,范垂钢,郝丽芳,李松庚,宋文立. 活性炭对低浓度萘的吸附性能.过程工程学报.2014年第14卷第2期,pp 253-257.
11、牛佳宁,张登峰,金锐,贾建丽,李松庚,林伟刚. 电石水解制备复合钙基吸附剂及其循环吸附CO2的特性.过程工程学报.2014年第14卷第2期。pp:340-344.
12、X M Yang, J.Y. Li, P. C.Li, M. Zhang, and J. Zhang. Determination of Activity Coefficients of Elements and Related Thermodynamic Properties of Fe–Si Binary Melts Based on the Atom–Molecule Coexistence Theory. Steel Res. Int, 2014, vol. 85(2), pp. 164–206.
13、X.M. Yang, M. Zhang, J. L. Zhang, P. C. Li, J. Y. Li, and J. Zhang. Representation of Oxidation Ability for Metallurgical Slags Based on the Ion and Molecule Coexistence Theory. Steel Res. Int, 2014, vol. 85(3), pp. 347–75.
14、X. M. Yang, P. C. Li, J. Y. Li, J. L. Zhang, M. Zhang, and J. Zhang. Representation Reaction Abilities of Structural Units and Related Thermodynamic Properties in Fe–P Binary Melts Based on the Atom–Molecule Coexistence Theory, Steel Res. Int, 2014, vol. 85(3), pp. 426–460.
15、J. Y. Li, M. Zhang, M. Guo, and X. M. Yang. Enrichment Mechanism of Phosphate in CaO–SiO2–FeO–Fe2O3–P2O5 Steelmaking Slags. Metall. Mater. Trans. B, 2014, vol. 45B(5), pp. 1666–82.
16、X. M. Yang, J. Y. Li, G. M. Chai, M. Zhang, and J. Zhang: Prediction Model of Sulfide Capacity for CaO–FeO–Fe2O3–Al2O3–P2O5 Slags in a Large Variation Range of Oxygen Potential Based on the Ion and Molecule Coexistence Theory. Metall. Mater. Trans. B, 2014, vol. 45B(6), pp. 2118–37.
17、李鹏程, 杨学民, 张建良: CaO–MgO–FeO–Fe2O3–SiO2炼钢渣系磷分配比的热力学模型. 北京科技大学学报, 2014, vol. 36(12), pp. 1608–14.
18、李晋岩, 张盟, 杨学民*:基于离子和分子共存理论的大氧势范围CaO–FeO–Fe2O3–Al2O3–P2O5 炉渣脱硫能力与潜力. 2014年(第十八届) 冶金反应工程学术会议论文集,2014,10月16-20日, pp: 158–72.
19、Xiaolong Liu,Xiaoxia Li,Jian Liu,Ze Wang,Bin Kong,Xiaomin Gong,XiaoZhen Yang,WeiLi Song,Li Guo.Study of High Density Polyethylene(HDPE)Pyrolysis with Reactive Molecular Dynamics .Polymer degradation and stability.2014,104: 62-70.
20、Xiaomin Gong,Ze Wang,Songgeng Li,Wenli Song,Weigang Lin.Coal Pyrolysis in a Laboratory-Scale Two-Stage Reactor: Catalytic Upgrading of Pyrolytic Vapors. CHEMICAL ENGINEERING & TECHNOLOGY.2014.37(12).pp: 2135-2142.
21、Xiaomin Gong,Ze Wang,Shuang Deng,Songgeng Li,WenLi Song.Weigang Lin.In-situcatalytic upgrading of coal pyrolysis vapors over Ce/Zr/Ni/Zn catalysts.Chemical Engineering technology. Accep
国际会议大会报告
[1] J. Y. Li, M. Zhang and X. M. Yang*: Desulfurization Ability or Potential of CaO–FeO–Fe2O3–Al2O3–P2O5 Slags in a Large Variation Range of Oxygen Potential Based on the Ion and Molecule Coexistence Theory. Abstract for World