基本信息

职称：讲师（校聘副教授）

学位：工学博士

专业：金属材料工程系

邮箱：lushuaidan@xatu.edu.cn

学习经历

2003年9月至2007年7月 昆明理工大学 学士

2010年9月至2012年12月 昆明理工大学 硕士

2013年9月至2019年7月 东北大学 博士

工作经历

2007年7月至2010年9月，中国黄金集团河南中原黄金冶炼厂，技术员

2019年9月至今，英国威廉希尔公司，讲师（校聘副教授）

招生信息

每年招收硕士生1名

研究方向

高熵合金的高温腐蚀与防护

热防护涂层

科研项目

[1] 陕西省科技计划项目（2021JQ-645），稀土活性元素效应对难熔高熵合金高温氧化行为的影响；主持

[2] 陕西省教育厅科研计划项目（20JK0684），Al含量对含硼难熔高熵合金组织和性能的调控研究，主持；

[3] 国家自然科学基金项目（51264022），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，参与。

发表论文

[1] 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.

[2] 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.

[3] 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.

[4] 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.

[5] 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.

[6] 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.

[7] 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.

[8] 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.

[9] 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.

[10] 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.

[11] 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.

[12] 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.

[13] 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.

[14] 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.

[15] 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.

[16] 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.

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

专利

[1] 一种锆基非晶合金的遗传制备方法，(授权号：CN103924170B)

[2] 一种微波加热的化学气相沉积设备，(授权号：CN105088194B)

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

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

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

[6] 一种高粘稠物料螺旋布料器，(授权号：CN202938615U）

[7] 一种高强塑自钝化难熔高熵合金及其制备方法，(申请号：CN202210366814. 1)

[8] 一种粒状赤泥吸附剂及其制备方法，(申请号：CN102600791A)

[9] 一种微波焙烧处理湿法炼锌铜渣的除氯方法，(申请号：CN102618717A)

[10] 一种水蒸汽活化微波焙烧综合回收含氯物料的方法，(申请号：CN202938615U)

[11] 一种微波低温造孔活化粒状赤泥制备多孔吸附材料的方法，(申请号：CN102876885A)

[12] 一种含磷的室温高塑性变形镁合金，(申请号：CN201410133282.2)

[13] 一种利用微波加热的化学气相沉积方法，(申请号：CN201510535892X)

[14] 一种转炉炉衬的快速修补方法，（2015105358934）

[15] 一种身管内膛表面的高熵合金薄膜及其制备方法，（申请号: 202210247384.1）

[16] 具有导电耐蚀涂层的燃料电池金属极板及其制备方法，（申请号: 202210206361.6）