研究队伍  
概况介绍
获奖
论文
专著
专利
成果转化
友情链接
中国科学院
国家发改委
国家自然科学基金委
中国科学技术部
中国科普博览
中国化工信息网
美国能源部
澳大利亚联邦科学与研究组织(CSIRO)
山西省科学技术厅
洁净能源创新研究院
您当前的位置:首页>研究队伍>专家人才
姓 名:
白进
性    别:
职 务:
职    称:
研究员
学 历:
博士研究生
通讯地址:
太原市桃园南路27号
电 话:
4040289
邮政编码:
030001
传 真:
电子邮件:
Stone@sxicc.ac.cn

简历:

2008.06,中国科学院大学,化学工艺,博士

2008.06-2010.12,中科院山西煤炭化学研究所,煤转化国家重点实验室,助理研究员;

2011.01-2016.08,中科院山西煤炭化学研究所,煤转化国家重点实验室,副研究员;

2016.09至今,中科院山西煤炭化学研究所,煤转化国家重点实验室,研究员

2018.04 至今,煤转化国家重点实验室,副主任


国际国内学术组织兼职

1. Advisory Board Member, 10th International Freiberg Conference, 2020, Shanghai, China

2. Session Chair, 9th International Freiberg Conference, 2019, Berlin, Germany

3. Session Chair, 2017 International Conference on Coal Science & Technology, 2017, Beijing, China

4. 全国煤炭标准化技术委员会委员,2018.01.16-2023.12.16

5.《燃料化学学报》青年编委

6.《煤炭转化》编委

7.《Processes》编委、特辑编辑

研究领域:

煤及生物质热转化、协同转化的应用基础研究;

熔渣化学及利用的应用基础研究

无机纤维制备及功能化
社会任职:

获奖及荣誉:

1. 大型气流床煤气化炉内湍流多相流动、传递与反应过程基础研究与工程应用,上海市科技进步一等奖,2015

2. 中科院青促会优秀会员(2016)

3. 侯德榜化工科学技术青年奖(2018),中国化工学会

4. 山西省学术技术带头人,2018

 

代表论著:

l  专著

李文,白进 《煤的灰化学》,2013,科学出版社,北京

l  国家标准

《煤灰黏度测定标准》GB/T 31424-2015

《焦炭中各种形态硫的测定方法》 GB/T 39769-2021

l  软件著作权

《煤灰熔渣流动性预测分析软件V1.0》(2019SR0215417

l  授权专利

一种改善煤灰熔渣黏温特性的助剂及其应用,

用于降低煤灰熔点的高效复合助熔剂及其制法和应用

一种改善粉煤气化煤灰熔渣黏温特性的助剂及应用

l  期刊论文(通讯和共同通讯)

[1]    Shi, W.; Bai, J.; Kong, L.; Li, H.; Bai, Z.; Vassilev, S. V.; Li, W. An overview of the coal ash transition process from solid to slag. Fuel 2021, 287.

[2]    D.H. Schwitalla, S. Guhl, J. K?rner, M. Laabs, et al. Meta-study on the effect of P2O5 on single phase slag viscosity and the effect of P2O5 induced liquid phase immiscibility on dispersion viscosity[J]. Fuel, 2021, 305: 121501.

[3]    D.H. Schwitalla, S. Guhl, M. Laabs, et al. Thermochemical and analytical approach to describe secondary slag phase formation and local process conditions in a full-scale BGL gasifier[J]. Fuel Processing Technology, 2021, 217: 106833.

[4]    Wenju Shi, M. Laabs, M. Reinm?ller, et al. The fusion mechanism of complex minerals mixture and prediction model for flow temperature of coal ash for gasification[J]. Fuel, 2021, 305: 121448.

[5]    Huaizhu Li, Lingxue Kong, Jin Bai, et al. Modification of ash flow properties of coal rich in calcium and iron by coal gangue addition[J]. Chinese Journal of Chemical Engineering, 2021, 35: 239-246.

[6]    Ji Wang, Lingxue Kong, Jin Bai, et al. Characterization of slag from anthracite gasification in moving bed slagging gasifier[J]. Fuel, 2021, 292: 120390.

[7]    Xi Cao, Lingxue Kong, Jin Bai, et al. Influence of water vapor on continuous cooling crystallization characteristics of coal ash slag[J]. Fuel, 2021, 303: 121241.

[8]    lingxue Kong, Jin Bai, Wen Li, et al. Viscosity-temperature property of coal ash slag at the condition of entrained flow gasification: A review[J]. Fuel Processing Technology, 2021, 215: 106751.

[9]    Mengjie Liu, Qili He, Jin Bai, et al. Char reactivity and kinetics based on the dynamic char structure during gasification by CO2[J]. Fuel Processing Technology, 2021, 211: 106583.

[10] Hao Lu, Baozi Peng, Zefeng Ge, et al. The viscosity and crystallization behavior of slag from co-gasification of coal and extraction residue from direct coal liquefaction residue at high temperatures[J]. Fuel, 2021, 285: 119119.

[11] Wenju Shi, M. Laabs, M. Reinm?llerc, et al. In-situ analysis of the effect of CaO/Fe2O3 addition on ash melting and sintering behavior for slagging-type applications[J]. Fuel, 2021, 285: 119090.

[12] Zongshuai Yuan, Ji Wang, Lingxue Kong, et al. Comparison study of fusibility between coal ash and synthetic ash[J]. Fuel Processing Technology, 2021, 211: 106593.

[13] Longfei Gao, Xiuchen Liu, Jin Bai, et al. Structure and flow properties of coal ash slag using ring statistics and molecular dynamics simulation: Role of CaO/Na2O in SiO2–Al2O3–CaO–Na2O[J]. Chemical Engineering Science, 2021, 231: 116285.

[14] LEE Roh Pin, Seidl Ludwig Georg, Qiuliang Huang, et al. An analysis of waste gasification and its contribution to China's transition towards carbon neutrality and zero waste cities[J]. Journal of Fuel Chemistry and Technology, 2021, 49(8): 1057-1076.

[15] Zefeng Ge, Lingxue Kong, Jin Bai, Xi Cao, Huiling Zhao, Huaizhu Li, Zongqing Bai, Bernd Meyer, Stefan Guhl, Wen Li. Crystallization kinetics and TCV prediction of coal ash slag under slag tapping conditions in an entrained flow gasifier. Fuel, 272, 2020, 117723.

[16] Xiaoming Li#, Lifei Zhi, Wenju Shi*, Lingxue Kong, Jin Bai*, Jianglong Yu, Markus Reinm?ller, Stefan Guhl, Bernd Meyer, Wen Li. Effect of K2O/Na2O on fusion behavior of coal ash with high silicon and aluminum level. Fuel. 2020. 265: 116964 (SCI).

[17] Xiaoming Li#, Xiaodong Chen#, Congbin Jiang, Jianping Ding Jinjun Guo, Lingxue Kong, Jin Bai*, Wen Li. Influence of the Slag–Crucible Interaction on Coal Ash Fusion Behavior at High Temperatures. Energy & Fuels. 2020, 34(3):87-3099 (SCI).

[18] Liu, Mengjie; Bai, Jin; Yu, Jianglong; Kong, Lingxue; Bai, Zongqing; Li, Huaizhu; He, Chong; Ge, Zefeng; Cao, Xi; Li, Wen. The correlation between char gasification characteristic at different stages and microstructure of char by combing XRD and Raman. Energy & Fuels. 2020, 34, 4, 4162-4172

[19] Xi Cao, Jin Bai*, et al. Effect of water vapor on viscosity behavior of coal slags with high silicon-aluminum level under gasification condition. Fuel. 2020.260:116351.

[20] Wenju Shi, Jin Bai*, et al. Effect of CaO/Fe2O3 ratio on fusibility of coal ashes with high silica and alumina levels and prediction. Fuel. 2020. 260:116369.

[21] Mengjie Liu, Jin Bai*, et al. The correlation between coal char structure and reactivity at rapid heating condition in TGA and heating stage microscope. Fuel. 2020. 260C: 116318

[22] Zefeng Ge, Jin Bai*, et al. Effect of CaO/Fe2O3 ratio on slag viscosity behavior under entrained flow gasification conditions. Fuel.2019.258: 1-10.

[23] Ji Wang, Lingxue Kong, Jin Bai*, Huiling Zhao, Stefan Guhl, Huaizhu Li, Zongqing Bai, Bernd Meyer, Wen Li. The role of residual char on ash flow behavior, Part 2: Effect of SiO2/Al2O3 on ash fusibility and carbothermal reaction. Fuel. 2019.225:1-8.

[24] Chong He, Jin Bai*, Alexander Ilyushechkin*, et al. Effect of chemical composition on the fusion behaviour of synthetic high-iron coal ash. Fuel. 2019.253: 1465-1472

[25] Chong He. Jin Bai*, et al. Effects of atmosphere on the oxidation state of iron and viscosity behavior of coal ash slag. Fuel. 2019. 243:41-51.

[26] Xiaoming Li, Lifei Zhi, Chong He, Stefan Guhl, Bernd Meyer, Lingxue Kong, Jin Bai*, Wen Li. The factors on metallic iron crystallization from slag of direct coal liquefaction residue SiO2-Al2O3-Fe2O3-CaO-MgO-TiO2-Na2O-K2O system in the entrained flow gasification condition. Fuel. 2019. 246:417-424.

[27] Xin Dai; Jin Bai*; Qing Huang; Zhen Liu; Xiaojing Bai; Ronggen Cao; Xiaodong Wen; Wen Li; Shiyu Du. Viscosity temperature properties from molecular dynamics simulation: the role of calcium oxide, sodium oxide and ferrous oxide. Fuel. 2019.237:163-169.

[28] Xi Cao; Lingxue Kong, Jin Bai*; Zefeng Ge; Chong He; Huaizhu Li; Zongqing Bai, Wen Li. Effect of water vapor on coal ash slag viscosity under gasification condition. Fuel. 2019.237:18-27.

[29] Chong He; Jin Bai*; Weicheng Li; Lingxue Kong; Jiang Xu; Stefan Guhl; Xiaoming Li; Zongqing Bai; Wen Li. Iron transformation behavior in coal ash slag in the entrained flow gasifier and the application for Yanzhou coal. Fuel. 2019.237:851-859.

[30] Tinggui Yan, Jin Bai*, et al. Improved prediction of critical-viscosity temperature by fusion behavior of coal ash. Fuel. 2019.253: 1521-1530.

[31] Zhigang Wang*. Lingxue Kong, Jin Bai*, Huaizhu Li, Chong He, Ting-gui Yan, Wen Li. Effect of vanadium and nickel on iron-rich ash fusion characteristics. Fuel. 2019.246:491-499.

[32] Huirong Zhang, Jin Bai*, Wen Li, Fangqing Chen. Carbothermal reactions of tobelite with coal char at high temperatures under N2 atmosphere. Journal of Analytical and Applied Energy. 2019. 137:220-226.

[33] Huirong Zhang, Jin Bai*, Wen Li, Fangqing Chen. Comprehensive evaluation of inherent mineral composition and carbon structure parameters on CO2 reactivity of metallurgical coke. Fuel. 2019.235:647-657.

[34] Zefeng Ge, Lingxue Kong. Jin Bai* et al. Effect of CaO/Na2O on slag viscosity behavior under entrained flow gasification conditions. Fuel Processing Technology. 2018.181:352-360.

[35] Wen-Ju Shi, LingXue Kong, Jin Bai*, Jiang Xu, WeiChengLi, ZongQingBai, WenLi. Effect of CaO/Fe2O3 on fusion behaviors of coal ash at high temperatures. Fuel Processing Technology. 2018. 181: 18-24.

[36] Ji Wang, Lingxue Kong, Jin Bai*, et al. The role of residual char on ash flow behavior, Part 1: The effect of graphitization degree of residual char on ash fusibility. Fuel. 2018.234:1173-1180.

[37] Daniel Schwitalla, Markus Reinm?ller, Clemens Forman, Christian Wolfersdorfa, Matthias Gootza, Jin Bai, Stefan Guhl, Markus Neuroth, Bernd Meyer. Ash and slag properties for co-gasification of sewage sludge and coal: An experimentally validated modeling approach. Fuel Processing Technology. 2018.175:1-9.

[38] Lingxue Kong, Jin Bai*, Huaizhu Li, Xiaodong Chen, Zongqing Bai, Wen Li. The mineral evolution during coal washing and its effect on ash fusion characteristics of Shanxi high ash coals. Fuel. 2018. 212:268-273.

[39] Wenju Shi, Xin Dai, Jin Bai*, Lingxue Kong, Jiang Xu, Xiaoming Li, Zongqing Bai, Wen Li. A new method of estimating the liquidus temperature of coal ash slag using ash composition. Chemical Engineering Science. 2018. 175:278-285.

[40] [26] Xin Dai, Jin Bai*, et al. Coal ash fusion properties from molecular dynamics simulation: the role of calcium oxide. Fuel. 2018. 216:760-767.

[41] Xiaodong Chen, Lingxue Kong, Jin Bai*, Xin Dai, Huaizhu Li, Zongqing Bai, Wen Li. The key for sodium-rich coal utilization in entrained flow gasifier: The role of sodium on slag viscosity-temperature behavior at high temperatures. Applied Energy. 2017.206:1241-1249.

[42] Xiao-Dong Chen, Lingxue Kong, Jin Bai*, Zongqing Bai, Wen Li. Study on fusibility of coal ash rich in sodium and sulfur by synthetic ash under different atmospheres. Fuel. 2017.202:175-183.

[43] Chong He, Jin Bai*, LingXue Kong, Stefan Guhl, Daniel Harry Schwitalla, Jiang Xu, ZongQing Bai, Wen Li. The precipitation of metallic iron from coal ash slag in the entrained flow coal gasifier: By thermodynamic calculation. Fuel Processing Technology. 2017.162:98-104.

[44] Tinggui Yan, Jin Bai*, Lingxue Kong, Zongqing Bai, Wen Li, Jiang Xu. Effect of SiO2/Al2O3 on fusion behavior of coal ash at high temperature. Fuel. 2017.193:275-283.

[45] Yan Tinggui, Kong Lingxue, Bai Jin*, Bai Zongqing, Li Wen. Thermomechanical analysis of coal ash fusion behavior. Chemical Engineering Science. 2016.147:74-82.

[46] Huirong Zhang, Jin Bai *, Lingxue Kong, et al. Thermal transformation of tobelite from coal at high temperatures and the kinetics and mechanism of dehydroxylation and deamination process. Fuel Processing Technology. 2016,144:203-211.

[47] Lingxue Kong, Jin Bai *, Zongqing Bai, Zhenxing Guo, Wen Li. The Internal and External Factor on Coal Ash Slag Viscosity at High Temperatures, Part 3: Effect of calcium on the viscosity-temperature curve. Fuel. 2016,179:10-16.

[48] Xin Dai, Jian He, Jin Bai*, Qing Huang, Xiaodong Wen, Lu Xie, Kan Luo, Jian Zhang, Wen Li, Shiyu Du. Ash Fusion Properties from Molecular Dynamics Simulation: Role of the Ratio of Silicon and Aluminum. Energy Fuels. 2016.30:2407-2413.

[49] Lingxue Kong, Jin Bai *, Zongqing Bai, Zhenxing Guo, Wen Li. The Internal and External Factor on Coal Ash Slag Viscosity at High Temperatures, Part 1: Effect of cooling rate on slag viscosity, measured continuously. Fuel. 2015.158: 968-975.

[50] Lingxue Kong, Jin Bai *, Zongqing Bai, Zhenxing Guo, Wen Li. The Internal and External Factor on Coal Ash Slag Viscosity at High Temperatures, Part 2: Effect of residual carbon. Fuel. 2015.158: 976-982.

[51] Huirong Zhang, Jin Bai *, Lingxue Kong, et al Behavior of Minerals in Typical Shanxi Coking Coal during Pyrolysis. Energy & Fuels. 2015. 29 (11), 6912-6919.

[52]Zhu Liu, Dabo Guan, Wei Wei, Steven J. Davis, Philippe Ciais, Jin Bai, et al. Reduced carbon emission estimates from fossil fuel combustion and cement production in China. Nature. 2015, 524: 335-338.


承担科研项目情况:

1.    NSFC面上项目,气流床煤气化条件下部分结晶熔渣黏温特性的预测及动态调控机制,2021.01-2025.1263万,在研,主持

2.    NSFC与德国科学基金会合作研究项目,液态排渣气化炉中灰渣黏度的若干关键问题,2018. 01-2020.12180万,结题,主持

3.    科技部重点研发项目子课题,水煤浆气化炉中水蒸气条件下熔渣的黏温特性及预测模型,2017.07-2021.0472万,结题,主持

4.    中科院“一带一路”合作项目,蒙古中低阶煤的分级转化特性及微量元素迁移,2018.01-2020.12100万,结题,主持

5.    中科院科研装备研制项目,高温气化条件下熔渣速度场和黏度的在线测量仪,2017.014-2.18.12300万,在研,主持

6.    中科院青年创新促进会优秀会员,中科院人才项目,2016/01-2018/12150万,结题,主持

7.    钙铁复合助剂调控山西典型无烟煤黏温特性的机理研究,山西省优青,2016/07-2018/1210万,结题,主持

8.    国家自然科学基金面上项目,21476247,煤气化熔渣中铁的价态分布对其流动性的影响及机理,2015/01-2018/1286万元,结题,主持

9.   山西煤炭化学研究所杰出青年人才B类,201606-2019/06150万,结题,主持

个人主页: