【获奖】 1. 2021年中国金属学会冶金科技二等奖
2. 指导学生获2020年全国模拟炼铁-炼钢-轧钢大赛二等奖二项,获优秀指导教师奖
3. 指导学生获2020年辽宁省创新方法大赛三等奖
4. 指导学生获2021年全国大学生冶金科技竞赛特等奖一项
【代表性学术著作、论文】 [1]Songtao Yang, Mi Zhou, Tao Jiang, et al. Effect of Basicity on Sintering behavior of Low-titanium Vanadium-titanium Magnetite[J].Transactions of Nonferrous Metals Society of China. 2015, 25, (6): 2087-2094.
[2]Songtao Yang, Mi Zhou, Tao Jiang, et al. Isothermal Reduction Kinetics of Chromium-Bearing Vanadium–Titanium Sinter Reduced with CO Gas at 1173 K[J]. JOM, 2019,71(8):2812–2820.
[3]Songtao Yang, Yong-liang Gao*, Xiangxin Xue,et al. Influence of titanium on transformation behaviour during continuous cooling of boron microalloyed steels[J]. Ironmaking & Steelmaking. 2018,45(10):959-968.
[4]Songtao Yang, Mi Zhou, Tao Jiang, et al. Isothermal reduction kinetics and mineral phase of chromium-bearing vanadium–titanium sinter reduced with CO gas at 873–1273 K[J]. International Journal of Minerals, Metallurgy, and Materials, 2018, 25(2):145-152.
[5]Songtao Yang, Mi Zhou, Tao Jiang, et al. Influence of Coke Ratio on the Sintering Behavior of High-Chromium Vanadium-Titanium Magnetite[J]. Minerals, 2017, 7(7):107.
[6]Songtao Yang, Mi Zhou, Tao Jiang, et al. Effects of Dolomite on Mineral Compositions and Metallurgical Properties of Chromium-Bearing Vanadium–Titanium Magnetite Sinter [J].Minerals, 2017, 7(11): 210.
[7]Songtao Yang, Mi Zhou, Tao Jiang, et al. Application of a water cooling treatment and its effect on coal-based reduction of high-chromium vanadium and titanium iron ore[J]. International Journal of Minerals, Metallurgy, and Materials. 2016,23(12):1353-1359.
[8]Weidang Tang, Songtao Yang*, Xiang-xin Xue*. Effect of Cr2O3 Addition on Oxidation Induration and Swelling Behavior of Chromium-Bearing Vanadium Titanomagnetite Pellets with Simulated Coke Oven Gas Injection into Blast Furnace[J]. International Journal of Minerals, Metallurgy, and Materials,2019,26(8):963-972.
[9]Mi Zhou, Songtao Yang*, Tao Jiang, et al. Influence of Coke Content on Sintering Process of Chromium-containing Vanadium-titanium Magnetite[J]. Journal of Wuhan University of Technology(Materials Science), 2018, 33(1):68-72.
[10]Weidang Tang, Song-tao Yang*, Xiang-xin Xue*. Effect of Co2O3 on Oxidation Induration and Reduction Swelling of Chromium-Bearing Vanadium Titanomagnetite Pellets with Simulated Coke Oven Gas[J]. Metals, 2019, 9(1):16.
[11]Weidang Tang, Song-tao Yang*, Xiang-xin Xue. Effect of B2O3 addition on oxidation induration and reduction swelling behavior of chromium-bearing vanadium titanomagnetite pellets with simulated coke oven gas[J].Transactions of Nonferrous Metals Society of China.2019, 29(7):1549-1559.
[12]Weidang Tang, Song-tao Yang, Gongjin Cheng, et al. Effect of TiO2 on the Sintering Behavior of Chromium-Bearing Vanadium–Titanium Magnetite[J]. Minerals, 2018, 8(7):263.
[13]Zixian Gao, Songtao Yang, Xiangxin Xue*. Extraction method for valuable elements of low-grade vanadia–titania magnetite[J]. Journal of Cleaner Production, 2019, 250, 119451.
[14]Liheng Zhan, Songtao Yang, Weidong Tang and Xiangxin Xue*. Investigations of MgO on Sintering Performance and Metallurgical Property of High-Chromium Vanadium-Titanium Magnetite[J]. Minerals, 2018, 9(5):324.
[15]Mi Zhou, Songtao Yang, Tao Jiang, et al. Influence of MgO in form of magnesite on properties and mineralogy of high chromium,vanadium,titanium magnetite sinters[J]. Ironmaking and Steelmaking, 2015, 42(3):217-225.
[16]Mi Zhou, Song-tao Yang ,Tao Jiang , et al. Influence of basicity on high chromium vanadium - titanium magnetite sinter properties, productivity and mineralogy[J]. JOM, 2015, 67(5):1203-1213.
[17]Mi Zhou, Song-tao Yang, Tao Jiang, et al. Effects of carbon content on sintering behavior of low-titanium vanadium-titanium magnetite[J]. Metallurgical Research & Technology. 2016, 113(6):612.
[18]Liheng Zhan, Songtao Yang, Weidong Tang, et al. Effect of coke breeze content on sintering mechanism and metallurgical properties of high-chromium vanadium-titanium magnetite.Ironmaking & Steelmaking, 2019, 10.1080/03019233.2019.1615814.
[19]Weidong Tang, Songtao Yang, Liheng Zhang, et al. Effects of basicity and temperature on mineralogy and reduction behaviors of high-chromium vanadium-titanium magnetite sinters[J].Journal of Central South University.2019,26(1):132-145.
[20]Mi Zhou, Tao Jiang, Song-tao Yang, et al. Vanadium-titanium magnetite ore blends optimization for sinter strength based on iron ore basic sintering characteristics [J].International journal of Mineral processing, 2015, 142: 125-133.
[21]Mi Zhou, Tao Jiang, Song-tao Yang, et al. Sintering behaviors and consolidation mechanism of high-chromium vanadium and titanium magnetite fines[J]. International Journal of Minerals, Metallurgy, and Materials, 2015, 22(9):917-925.
[22]Weidang Tang, Xiang-xin Xue*, Song-tao Yang, et al. Influence of basicity and temperature on bonding phase strength, microstructure, and mineralogy of high-chromium vanadium–titanium magnetite[J]. International Journal of Minerals, Metallurgy, and Materials, 2018, 25(8):871-880.
[23]Weidang Tang, Songtao Yang, Xiangxin Xue*. Effect of V2O5 Addition on Oxidation Induration and Swelling Behavior of Chromium-BearingVanadium Titanomagnetite Pellets with Simulated Coke Oven Gas Injection into Blast Furnace[J]. ISIJ international, 2019,59(6):988-997.
[24]Mi Zhou, Tao Jiang, Songtao Yang, et al. Optimization utilization of vanadium-Titanium iron ore in sintering based on orthogonal method Source[J]. Metalurgija, 2016,55(4):581-584.
专著
1 薛向欣, 杨松陶, 张勇. 高炉流程冶炼含铬型钒钛磁铁矿-理论与实践[M]. 北京: 科学出版社, 2020.
【专利】 [1]薛向欣,姜涛,杨松陶,周密,段培宁. 一种含铬型钒钛磁铁精矿配加弃渣制备烧结矿的方法[P]. 辽宁:CN104480299A,2015-04-01.
[2]薛向欣,姜涛,杨松陶,周密,段培宁. 一种酸性含铬型钒钛烧结矿的制备方法[P]. 辽宁:CN104630458A,2015-05-20.
[3]薛向欣,姜涛,杨松陶,周密,段培宁. 一种钛铁精矿烧结制备烧结矿的方法[P]. 辽宁:CN104630457A,2015-05-20
[4]薛向欣,周密,姜涛,杨松陶,段培宁. 一种提高含铬型钒钛烧结矿转鼓强度的方法[P]. 辽宁:CN104388669A,2015-03-04.
[5]薛向欣,周密,姜涛,杨松陶,段培宁. 一种高铬型钒钛烧结混合球料的制备方法[P]. 辽宁:CN104630451A,2015-05-20
[6]薛向欣,周密,姜涛,杨松陶,段培宁. 一种用高铬型钒钛混合料制备烧结矿的方法[P]. 辽宁:CN104630449A,2015-05-20.
[7]薛向欣,周密,姜涛,杨松陶,段培宁. 一种选取含铬型钒钛混合料中配加的铁矿粉的方法[P]. 辽宁:CN104630453A,2015-05-20.
[8]薛向欣,滕艾均,姜涛,杨松陶. 一种从含铬钒物料中分离提取钒的方法[P]. 辽宁:CN108179265A,2018-06-19.
[9]薛向欣,滕艾均,姜涛,杨松陶. 一种含铬钒渣中回收铬和钒的方法[P]. 辽宁:CN108048668A,2018-05-18.
[10]薛向欣,汤卫东,杨松陶,杨合,张立恒,程功金,高子先. 一种酸性高铬型钒钛磁铁矿制备高碱度烧结矿的方法[P]. 辽宁:CN107937712A,2018-04-20.
[11]薛向欣,汤卫东,杨松陶,杨合,高子先,程功金,张立恒. 一种酸性低铬型钒钛磁铁矿制备高碱度烧结矿的方法[P]. 辽宁:CN107937713A,2018-04-20.
[12]薛向欣,汤卫东,杨松陶,杨合,张立恒,程功金,黄壮. 一种低铬型钒钛磁铁矿配加钛铁矿制备烧结矿的方法[P]. 辽宁:CN107937714A,2018-04-20.
[13]薛向欣,汤卫东,杨松陶,杨合,姜涛. 一种高铬型钒钛磁铁矿配加铬铁矿制备球团矿的方法[P]. 辽宁:CN107937715A,2018-04-20.
[14]薛向欣,汤卫东,杨松陶,杨合,张立恒,程功金,高子先. 一种低铬型钒钛磁铁矿配加铬铁矿制备烧结矿的方法[P]. 辽宁:CN107881325A,2018-04-06.
[15]薛向欣,汤卫东,杨松陶,杨合,张立恒,程功金,高子先. 一种高铬型钒钛磁铁矿配加普通铁矿制备烧结矿的方法[P]. 辽宁:CN107881327A,2018-04-06.
【主要科研项目】 1. 国家自然科学基金面上项目“钒钛矿高炉还原软熔过程中矿-焦非稳态耦合行为及一体化表征”(52174319),主持;
2.国家科技部2012年度对俄科技合作重大专项项目:“高铬型钒钛磁铁矿冶炼和钒钛铬分离提取技术的联合研发”(2012DFR60210),参与;
3.2012年度国家高技术研究发展计划(863计划):“高钒高铬型俄罗斯钒钛磁铁矿高效清洁综合利用” (2012AA062304),参与;
4.国家自然基金重大项目“钒钛资源冶金过程有价组元强化迁移规律及分离理论”中“钒钛组元相际迁移的动力学规律及其影响规律”(51090384),参与。
