基本信息

姓名：黄士星                              出生年月：1991-11

学历：博士研究生                         学位：工学博士

职称：讲师                                 邮箱：hsxing1991@163.com

教育经历

2017.9~2021.10      东北大学             材料科学与化工学院    材料学         博士

2014.9~2017.6       辽宁工业大学         材料科学与化工学院    材料学          硕士

2010.9~2014.6       辽宁工业大学        材料科学与化工学院    材料物理       学士

工作经历

2021.11-至今     西安工业大学     讲师

研究方向

高性能钛合金成分设计、组织调控及强韧化研究

高性能钛基复合材料制备与成型技术研究

镁合金热变形行为及微观机制研究

招生信息                                                 

每年招收1-2名硕士研究生

科研项目

（1）陕西省科学技术厅 2022年秦创原高层次人才项目（QCYRCXM-2022-147），化工用大尺寸高性能镁合金板材制造与应用技术，2023-01至2025-12，18万元，在研，主持；

（2）陕西省科学技术厅 陕西省自然科学基础研究计划一般项目（青年2023-JC-QN-0530），近alpha钛合金中beta相塑性变形调控机制研究，2023-01至2024-12，5万元，在研，主持.

发表论文

1. S.X. Huang, Q.Y. Zhao, Y.Q. Zhao, C. Lin, C. Wu, W.J. Jia, C.L. Mao, V. Ji, Toughening effects of Mo and Nb addition on impact toughness and crack resistance of titanium alloys, Journal of Materials Science and Technology, 2021, 79, 147-164. (SCI, IF: 10.32)

2. S.X. Huang, Q.Y. Zhao, C. Lin, C. Wu, Y.Q. Zhao, W.J. Jia, C.L. Mao, In-situ investigation of tensile behaviors of Ti-6Al alloy with extra low interstitial, Materials Science & Engineering A, 2021, 809, 140958. (SCI, IF: 6.044)

3. S.X. Huang, Q.Y. Zhao, C. Lin, C. Wu, Y.Q. Zhao, W.J. Jia, C.L. Mao, Effects of oxygen content on Charpy impact properties and crack resistance of α titanium alloys, Materials Science & Engineering A, 2021, 818, 141394. (SCI, IF: 6.044)

4. S.X. Huang, Q.Y. Zhao, C. Wu, C. Lin, Y.Q. Zhao, W.J. Jia, C.L. Mao, Effects of β-stabilizer elements on microstructure formation and mechanical properties of titanium alloys, Journal of Alloys and Compounds, 2021, 876, 160085. (SCI, IF: 6.371)

5. S.X. Huang, Y.Q. Zhao, J.S. Yu, C. Lin, C. Wu, W.J. Jia, Effects of β-stabilizer elements on microstructure formation and mechanical properties of titanium alloys, Journal of Alloys and Compounds, 2020, 826, 154128. (SCI, IF: 6.371)

6. C. Wu, Y.Q. Zhao, S.X. Huang, Q.Y. Sun, L. Zhou, Effect of cooling rate on a variant selection and microstructure evolution in a near β Ti-5Al-3Mo-3V-2Cr-2Zr-1Nb-1Fe alloy, Journal of Alloys and Compounds, 2020, 841, 155728. (SCI, IF: 6.371)

7. C. Wu, Y.Q. Zhao, S.X. Huang, L. Lei, Q.Y. Sun, L. Zhou, Microstructure tailoring and impact toughness of a newly developed high strength Ti-5Al-3Mo-3V-2Cr-2Zr-1Nb-1Fe alloy, Materials Characterization, 2021, 175, 111103. (SCI, IF: 4.537)

8. J.S. Yu, Q.Y. Zhao, S.X. Huang, Y.Q. Zhao, J.W. Lu, L.L. Dong, N. Tian, Enhanced mechanical and tribological properties of graphene nanoplates reinforced TC21 composites using spark plasma sintering, Journal of Alloys and Compounds, 2021, 873, 159764. (SCI, IF: 6.371)

9. J.S. Yu, Q.Y. Zhao, S.X. Huang, Y.Q. Zhao, Y. Zhou, J.W. Lu, L.L. Y.S. Zhang. Effect of sintering temperature on microstructure and properties of graphene nanoplatelets reinforced TC21 composites prepared by spark plasma sintering, Journal of Alloys and Compounds, 2021, 879, 160346. (SCI, IF: 6.371)

10. L. Lei, Q.Y. Zhao, Y.Q. Zhao, S.X. Huang, C. Wu, W.J. Jia, W.D. Zeng, Study on the intrinsic factors determining impact toughness of TC21 alloy, Materials Characterization, 2021, 177: 111164. (SCI, IF: 4.537)

11. L. Lei, Y.Q. Zhao, Q.Y. Zhao, C. Wu, S.X. Huang, W.J. Jia, W.D. Zeng, Impact toughness and deformation modes of Ti-6Al-4V alloy with different microstructures, Materials Science & Engineering A, 2021, 801, 140411. (SCI, IF: 6.044)

12. J. Wang, Y.Q. Zhao, W. Zhou, Q.Y. Zhao, S.X. Huang, W.D. Zeng, In-situ investigation on tensile deformation and fracture behaviors of a new metastable β titanium alloy, Materials Science & Engineering A, 2021, 801, 140411. (SCI, IF: 6.044)

13. C. Lin, S.X. Huang, G.L. Yin, A.M. Zhang, Z.W. Zhao, Y.Q. Zhao, A simple model to ascertain the initial formation concentration of athermal ω phase in titanium alloys, Computational Materials Science, 2016, 123, 263-267. (SCI, IF: 3.572)

专利

1. 赵永庆, 黄士星, 吴聪, 一种钛合金断口剖面的EBSD试样制备方法: 中国, ZL 20191 0921930.3. （授权）

基本信息

姓名：卢帅丹

职称：副教授 硕士生导师

学位：工学博士

专业：金属材料工程

邮箱：lushuaidan@xatu.edu.cn

学习经历

2013年9月至2019年7月  东北大学 博士

2010年9月至2012年12月 昆明理工大学 硕士

2003年9月至2007年7月  昆明理工大学 学士

工作经历

2023年12月至今，西安工业大学，副教授

2019年9月至2023年12月，西安工业大学，讲师

招生信息

每年招收硕士研究生2名

教育教学

主讲课程：《特种表面制备方法》

研究方向

[1] 火炮身管延寿内涂层技术

[2] 高超声速飞行器热防护

学术兼职

《Corrosion Science》、《Journal of alloys and compounds》等期刊审稿人

科研项目

[1] 中央军委装备发展部-国防科技重点实验室基金，C/C复合材料***高熵合金涂层构建及其烧蚀机理研究，50万，主持

[2] 陕西省科技计划项目，稀土活性元素效应对难熔高熵合金高温氧化行为的影响，3万，主持

[3] 陕西省教育厅科研计划项目，Al含量对含硼难熔高熵合金组织和性能的调控研究，2万，主持

[4] 西安市未央区科技计划项目，C/C复合材料抗烧蚀高熵合金涂层，3万，主持

[5] 企业委托项目，高熵合金在飞行器高温燃气阀阀芯的应用，10万，主持

[6] 科技部国家重点研发计划项目，离子轰击条件下反应磁控沉积高熵合金氮化物薄膜技术研究与开发，100万元，参与（4/15）

[7] 陕西省军民融合发展项目，高超音速***涂层的关键技术研究，2023-01至2024-12，200万元，参与（2/12）

[8] 陕西省军民融合发展项目，高性能***涂层的关键技术研究，2022-01至2023-12，200万元，参与（6/12）

[9] 企业委托项目，高熵合金材料及涂层技术，200万，参与（5/6）

[10] 国家自然科学基金项目，微波低温造孔活化粒状赤泥制备新型多孔吸附材料的应用基础研究，53万，参与（3/5）

[11] 工信部科技成果转化项目，微波冶金反应器及其应用的关键技术，参与

荣誉奖励

[1] 西安工业大学优秀共产党员（2022年）

[2] 西安工业大学毕业设计（论文）优秀指导教师（2022年）

[3] 辽宁省2016届普通高等学校优秀毕业生

[4] 博士研究生国家奖学金（2014年度、2015年度）

发表论文

[1] Xueyang Zhou, Jian Chen, Rengen Ding, Haoyue Wu, Shuaidan Lu et al. Effect of Mn on microstructure and tensile properties of as-cast Al0.5CoFeNiC0.1 high-entropy alloy, Materials Science & Engineering, A, 2023, 873:144951.

[2] Xueyang Zhou, Jian Chen, Rengen Ding, Haoyue Wu, Shuaidan Lu et al. A novel coherent particles-reinforced FCC-based high-entropy superalloy with superior high-temperature compressive properties, Materials Science & Engineering, A, 2023, 872:144947.

[3] Wenting Shao, Shangkun Wu, Wei Yang, Jiahua He, Shuaidan Lu et al. Effect of modulation period on microstructure and mechanical properties of (AlSiTiVNbCr)N/(AlSiTiVNbCr)CN nano-multilayer films, Vacuum, 2023, 207:111660.

[4] Shuaidan Lu, Xiaoxiao Li, Xiaoyu Liang et al. Effect of Al content on the oxidation behavior of refractory high-entropy alloy AlMo_0.5NbTa_0.5TiZr at elevated temperatures, International Journal of Refractory Metals and Hard Materials, 2022, 105: 105812.

[5] Shuaidan Lu, Xiaoxiao Li, Xiaoyu Liang et al. Effect of Y additions on the oxidation behavior of vacuum arc melted refractory high-entropy alloy AlMo_0.5NbTa_0.5TiZr at elevated temperatures, Vacuum, 2022, 201: 111069.

[6] Shuaidan Lu, Xiaoxiao Li, Xiaoyu Liang et al. Effect of Ho Addition on the Glass-Forming Ability and Crystallization Behaviors of Zr₅₄Cu₂₉Al₁₀Ni₇ Bulk Metallic Glass, Materials, 2022, 15(7), 2516.

[7] Shuaidan Lu, Xiaoxiao Li, Xiaoyu Liang et al. Effect of V and Ti on the Oxidation Resistance of WMoTaNb Refractory High-Entropy Alloy at High Temperatures, Metals, 2022, 12(1), 41.

[8] Shuaidan Lu, Shuchen Sun, Xiaoxiao Huang et al. The effect of yttrium addition on the air oxidation behavior of Zr-Cu-Ni-Al bulk metallic glasses at 400-500 °C. Corrosion Science, 2018, 137: 53-61.

[9] Shuaidan Lu, Shuchen Sun, Kuanhe Li et al. The effect of Y addition on the crystallization behavior of Zr-Cu-Ni-Al bulk metallic glasses. Journal of alloys and compounds, 2019, 799: 501-512.

[10] Shuaidan Lu, Shuchen Sun, Xiaoxiao Huang et al. Optimization of recovering cerium from the waste polishing powder using response surface methodology. Green Processing and Synthesis, 2017, 6 (2): 217-224.

[11] Shuaidan Lu, Shuchen Sun, Xiaoxiao Huang et al. Deposition behavior of TiB₂ by microwave heating chemical vapor deposition (CVD). Green Processing and Synthesis, 2015, 4(3): 203-208.

[12] Shuaidan Lu, Shuchen Sun, Xiaoxiao Huang et al. Glass-forming ability and mechanical properties of a Zr_52.8Cu_29.1Ni_7.3Al_9.8Y₁ bulk metallic glass prepared by hereditary process. Green Processing and Synthesis, 2016, 5(1):65-70.

[13] Shuaidan Lu, Shaohua Ju, C. Srinivasakannan et al. Dechlorination mechanism of CuCl residue from zinc hydrometallurgy by microwave roasting. High Temperature Materials and Processes, 2015, 34(2): 147-154.

[14] Shuaidan Lu, Yi Xia, Changyuan Huang et al. Removing chlorine of CuCl residue from zinc hydrometallurgy by microwave roasting. Journal of Central South University, 2014, 21(4): 1290-1295.

[15] Shuaidan Lu, Shuchen Sun, C. Srinivasakannan et al. Optimization of Microwave Roasting for Dechlorination of CuCl Residue from Zinc Hydrometallurgy. Journal of Microwave Power and Electromagnetic Energy, 2014, 48(1): 61-70.

[16] Shaohua Ju, Shuaidan Lu, Jinhui Peng et al. Removal of cadmium from aqueous solutions using red mud granulated with cement. Transactions of Nonferrous Metals Society of China, 2012, 22: 3140-3146.

[17] Shuaidan Lu, Shaohua Ju, Jinhui Peng et al. New process for the granulation of red mud and assessment of its physical properties. TMS Annual Meeting & Exhibition: T.T. Chen Honorary , 2012, 501-507.

[18] Shuaidan Lu, L. T. Q. Xuan, Shaohua Ju et al. Removal of methylene blue from aqueous solutions using a novel granular red mud (GRM) mixed with cement. TMS Annual Meeting: Alumina and Bauxite, 2013.

[19] Shuaidan Lu, Shaohua Ju, Changyuan Huang et al. The contrastive studies of microwave and conventional roasting CuCl residue from zinc hydrometallurgy. TMS Annual Meeting: Characterization of Minerals, Metals and Materials, 2013.

[20] Shuaidan Lu. Process optimization of removing chlorine of zinc dross using microwave roasting. TMS Annual Meeting: Characterization of Minerals, Metals and Materials, 2014.

授权发明专利

[1] 具有导电耐蚀涂层的燃料电池金属极板及其制备方法，（CN114540752B）

[2] 一种锆基非晶合金的遗传制备方法，(CN103924170B)

[3] 一种微波加热的化学气相沉积设备，(CN105088194B)

[4] 一种使用稀土元素改善铝硅合金表面裂纹的方法，（CN104894416B）

[5] 一种从电弧炉制得二硼化钛中反浮选脱碳的方法，(CN105080727B)

[6] 一种微波连续焙烧处理湿法炼锌含氯铜渣的方法，(CN102839279B)