项目名称编号/项目类别/项目经费/起止时间/角色

国家重点研发项目，2023YFB3710002，大规格高品质钛青铜合金铸坯制备关键技术2023-11至2026-10，120.08万, 在研

国家重点研发项目，2021YFB3501003，宽频电磁屏蔽高强高导稀土铜铁合金，2021-12至2025-11，60万, 主持

服役环境下Cu~CrZr合金的损伤行为及机制 51104113 国家自然基金 25万20122014 主持

高光吸率铜合金选区激光熔化复合深冷成形机理与调控机制 52174371 国家自然基金 58万 2022-2025 主持

轨道交通用高强高导铜合金技术开发及产业化19JC025教育厅地方专项10万2019〜2020主持

高强β钛合金的热变形机制及微观组织调控2019KW064国际科技合作计划项目5万2019〜2020主持

新型超高强β钛合金的开发及其关键技术研究2012M511981博士后基金5万2012〜2013主持

高性能铜铬锆合金的加工工艺与性能研究2010JK650教育厅专项项目2万20102012主持

连续变断面循环挤压制备块体超细晶材料的技术基础研究2009JQ6010科技厅面上项目2万20092011.主持

紧固件用超高强钛合金技术开发及产业化14JF013教育厅工业攻关10万2014〜2015主持

航空用超高强β钛合金关键技术研究2016GY207省科技厅工业攻关项目10万20162017主持

高性能铜铬锆合金棒材关键技术开发YY1503金川预研项目2万20152016主持

大功率机车用高性能铜合金关键技术开发CXY西安市科技局5万20172018主持

大规格块体金属在连续变断面循环挤压中的细化机理研究51101116国家自然基金青年项目25万2012〜2014参与

搅拌摩擦加工超细镁合金塑韧化机制研究51404180国家自然基金青年项目25万20152017参与

超高强铝合金和镁合金同种/异种材料搅拌摩擦焊接技术及相关基础U1760201国家自然科学基金钢铁基金重点项目260万2018〜2021参与

高精度钛/锆合金挤压型材制备技术(2017YFB0306200)国家重点研发计划项目5137万2017〜2021参与

钛及钛合金搅拌摩擦焊接技术开发CXY1124(4)西安市工业应用技术研发8万2011〜2012参与

发表学术论文80余篇，其中SCI、EI收录60余篇，主编和参编教材5部，获国家发明专利9项。

[1]      Qingjuan Wang, Xinlong Ren, Lei Wang, et al Study on Hot DeformationBehavior and Dynamic Recrystallization Mechanism of Cu-Ti-Fe Alloy[J]. AdvancedEngineering Materials, 2024, 26(3).

[2]      Qingjuan Wang, Yufeng Zhang, Kuaishe Wang, et al  Effect of process parameters and heattreatment on the microstructure and properties of CuCrZr alloy by selectivelaser melting[J].Materials Science & Engineering A, 2022.

[3]      Qingjuan Wang, Huijun Shao, Xi Zhang, et al Study of thermal behavior andmicrostructure formation mechanism of CuCrZr alloy melted by laser powder bedfusion [J] Materials Characterization, 2023.

[4]      Qingjuan Wang, Jiale Song, Wen Wang, et al The Influence of HeatTreatment on Microstructure and Properties of Selective Laser Melting CuCrZrAlloy [J] Advanced Engineering Materials, 2024.

[5]      Qingjuan Wang, Beite Gao. Dynamic and static softening mechanisms ofcommercial-purity Zr during double-stage hot compressive deformation[J].Materials Science & Engineering A, 2021, 820.

[6]      QingjuanWang,Tingli Hou, Wei Wang, Guoliang Zang, Yuan Gao, Kuaishe Wang. Tribologicalbehavior of black phosphorus nanosheets as water-based lubrication additives,Friction, 2021, 9: 1-14.

[7]      QingjuanWang, JinchengWu, Libo Tong, Wei Wang, Renkun Yin, Peng Cao. Phase Transformation andKinetics in Metastable β Titanium Alloy During Isothermal Treatment, AdvancedEngineering Materials, 2021, 23(2): 1-11.

[8]      QingjuanWang, XiangjunLi, Kuaishe Wang, , Bing Zhang, Jun Cai, Libo Tong, Yaojia Ren, Zhouyu Zeng,Jun Dang. ElevatedTemperature Compression Deformation Behavior of Commercial Pure Zr Combinedwith the Constitutive Equation and Processing Map[J]. Advanced EngineeringMaterials, 2019, 22(2).

[9]      QingjuanWang, Tingli Hou, WeiWang, et al. Tribological propertiesof black phosph orus nanosheets as oil-based lubricant additives for titanium alloy-steelcontacts[J]. Royal Society Open  Science.2020, 7(9): 200530

[10]   Qingjuan Wang , DanLiu, Libo Tong *, Ying Zhou, Wei Wang , Haixiong Zhou and Ruixue Fan EnhancedStress Corrosion Cracking Resistance of Ultrafine-Grained Cu-Cr-Zr AlloyFabricated via Equal-Channel Angular Pressing, Metals 2019, 9, 824.

[11]   Qingjuan Wang, Jiamin Shi, Jun Cai and Yaoyao Feng, DeformationBehavior and Processing Map during Isothermal Hot Compression of 49MnVS3Non-Quenched and Tempered Steel, High Temp. Mater. Proc. 2019; 38: 452–460

[12]   Wei Wang, Haixiong Zhou, QingjuanWang*, Jie Jin*, Yaling Sun,Kuaishe Wang. High-Temperature TribologicalBehavior of the Ti-22Al-25Nb (at. %) Orthorhombic Alloy with Lamellar OMicrostructures. Metals 2019, 9(1), 5.

[13]   Wei Wang, Han Ziru, Qingjuan Wang*, et al. TribologicalProperties of Ti2AlNb Matrix Composites Containing Few-Layer GrapheneFabricated by Spark Plasma Sintering[J]. Metals, 10(7): 924.

[14]   Wei Wang, Han Ziru, Qingjuan Wang*, et al. Influence of HeatTreatment on the Microstructure Evolution and Mechanical Properties of Graphene/Ti2AlNbComposites Synthesized via Spark Plasma Sintering[J]. Journal of Materials Engineering and Performance,2020.(JMEP-20-03-20118.R1).

[15]   Wei Wang, Haixiong Zhou, Qingjuan Wang*, Ziru Han, et al. Preparation andtribological behavior of Ti2AlNb/Ag self-lubricating composites[J]. Journal of Materials Engineering and Performance, 2020,(JMEP-20-01-19738.R1)

[16]   Wang Q.J., Du Z.Z., L. Luo, W. Wang, Fatigue properties of ultra-fine grain Cu–Cralloy processed by equal-channel angular pressing, Journalof Alloys and Compounds, 2012, 526（15）, 39-44

[17]    Wang Q. J., Xu CZ, Zheng MS, Zhu JW. Fatigue Crack Initiation LifePrediction of Ultra-fine Grain Chromium-bronze Prepared by Equal-channelAngular Pressing[J]. Materials Science and Engineering: A, 2008, 459（1-2）: 303-308.

[18]   Wang Q. J., Xu CZ, ZhengMS, Zhu JW. Investigation on Semi-conductive Properties of Passive Films Formedon Copper in Chromate Solutions [J]. Thin Solid Film，2009, 517:1995-1999.

[19]   Wang Q. J, Zhang P.P.,Liu C.Y.,Principle of the Continuous Variable Cross-Section Recycled Extrusion(CVCE)Process, Advanced Materials Research Vols. 418-420 (2012) pp 1400-1404

[20]   Wang Q. J, Du Z. Z , Liu X. Y., Ludvík Kunz,Fatigue Property andFatigue Cracks of Ultra-fine Grained CopperProcessed by Equal-channel AngularPressing, Materials Science Forum Vol. 682 (2011) pp 231-237

[21]   Wang Q. J., Y.C.Wang, DuZhong ze, Investigation on Corrosion Behaviors of Ultra-Fine Grain Copper in3.5%NaCl Solution Materials Science Forum, Vols, 2011 667-669 :1125-1130.

[22]   Xu CZ, Wang Q. J., Zheng MS, Zhu JW,et al. Microstructure and properties ofultra-fine grain Cu–Cr alloy prepared by equal-channel angular pressing[J].Materials Science and Engineering: A, 2007,459（1-2）: 303-308.

[23]   Xu CZ, Wang Q. J., Zheng MS, Li JD, ZhuJW, et al. Fatigue behavior and damage characteristic of ultra-fine grain lowpurity copper processed by equal-channel angular pressing (ECAP)[J]. MaterialsScience and Engineering: A. 2008,475. 249-256.