马成龙

职称

副教授

职务

院长助理

联系方式

chenglongma@jiangnan.edu.cn

办公室：机械楼B307

欢迎想从事激光3D打印方向的同学报考研究生！

教育背景

2010.09-2014.06，南京航空航天大学，材料科学与工程，学士；

2014.09-2020.11，南京航空航天大学，材料加工工程，硕博连读，博士；

2019.01-2019.02，德国Fraunhofer激光技术研究所，学术访问；

2019.11-2020.05，英国卡迪夫大学，材料加工工程，博士联合培养。

学术兼职

■ 中国机械工程学会增材制造技术分会第二届委员会青年委员；

■ 中国机械工程学会高级会员；

■ 长三角钢铁产业发展协会全国增材制造专家委员会青年委员；

■ 江苏省铸造学会常务理事；

■ 《Additive Manufacturing Frontier》青年编委；

■ 《Metals》编委；

■ Advanced Science、International Journal of Extreme manufacturing、International Journal of Machine Tool and Manufacture、Journal of Materials Research and Technology、Physics of Fluids、Journal of Alloys and Compounds等十几种SCI期刊受邀审稿人；

研究方向

高性能金属及其复合材料激光3D打印，形状记忆合金相变行为与超弹性，弹热制冷材料，仿生功能结构激光3D打印

在研项目

(1) 中国博士后科学基金项目资助(2023M742541)，高性能金刚石钻头多材料仿生布局及其激光增材制造成形机理，2024.01-2025.12，主持，8万，在研；

(2) 国家自然科学基金青年项目(No.52105345)，基于激光增材制造的NiTi基仿生手性多孔质结构及其弹热制冷机理，2022.01-2024.12，主持，30万，在研；

(3) 国防科技基础研究173项目基础加强计划技术领域基金(No. 2021-JCJQ-JJ-0120)，TiAl基***关键技术研究，2022.10-2024.10，主持，80万，在研；

(4) 中央高校基本科研计划项目，基于生物启迪的NiTi基仿生手性弹热材料及其激光增材制造一体化制备，2022.01-2023.12，主持，已结题；

(5) 国家自然科学基金委员会-中国工程物理研究院NSAF联合基金重点项目“大跨尺度多层级仿生多孔质NiTi减振材料增材制造基础研究”（No. U1930207），2020.07-2023.12，参与，280万，已结题；

(6) 江苏省重点研发计划子课题“异质材料复杂整体构件激光复合增材制造软件系统研发”（No. SBE2022020081），2022.07-2026.06，参与，300万，在研。

学术成果与奖励

• 2024年江南大学青年教师教学竞赛二等奖

• 2023年度江苏省铸造学会杰出青年人才奖

• 2023年度江南大学研究生教学成果奖一等奖（5/5）

• 2023年第二届全国博士后创新创业大赛优胜奖（3/5）

• 2023年江苏省首届博士后创新创业大赛创新团队优胜奖（3/5）

• 2023年度第三届江苏省高校教师教学创新大赛二等奖（4/4）

• 2021年度江南大学足球购买平台推荐贡献奖

• 2021年度江南大学教学成果奖一等奖（5/5）

近期成果

累计发表SCI期刊论文50余篇，其中以第一作者及通讯作者在Composites Part B、Mater. Des.、Appl. Surf. Sci、Mater. Character.等期刊发表SCI论文18篇和国际学术会议论文1篇，H因子28；申请国家发明专利12项，其中获得授权8项；在国际/国内重要学术会议作口头/邀请报告10余次。

近期论文

[1] Peng X,*Ma C L, Yuan L H, Dai D H, Zhu D H, Wu M P. Understanding the role of laser processing parameters and position-dependent heterogeneous elastocaloric effect in laser powder bed fused NiTi thin-walled structures.Smart Materials and Structures, 2024, 33: 045003

[2]*Ma C L, Peng X, Zhu D H, *Dai D H, Yuan L H, Ma S, Fang Z Y, *Wu M P. Laser additive manufactured NiTi-based bioinspired helicoidal structure with excellent superelasticity and energy absorption capacity.Journal of Manufacturing Processes, 2023, 108: 610-623.

[3] Zhuo Z^#, Fang Z Y^#,*Ma C L, Xie Z W, Peng X, Wang Q L, Miao X J, *Wu M P.Influence of LaB₆inoculant on the thermodynamics within the molten pool and subsequent microstructure development andcrackingbehavior of laser powder bed fused TiAl-based alloys.Journal of Materials Research and Technology, 2023, 27: 2363-2381.

[4]*Ma C L, *Fang Z Y, Wu M P, Miao X J, Wang Q L. Interfacial Stress Development and Cracking Susceptibility during Laser Powder Bed Fusion of Random TiB₂-Particle-Reinforced AlSi10Mg Matrix Composites.Metals, 2023, 13(8), 1405.

[5] Peng X, Yuan L H, Dai D H, Liu Y, Li D Y, Zhu D H, Fang Z Y,*Ma C L, *Gu D D, *Wu M P. A new class of additive manufactured NiTi-based hierarchically graded chiral structure with low-force compressive actuation for elastocaloric heat pumps.Chinese Journal of Mechanical Engineering: Additive Manufacturing Frontiers, 2023, 100077.

[6] Luo W H, Fang Z Y, *Ma C L, *Wu M P, Zhuo Z. Ball-milling treatment of Nb and B nanoparticles modified TiAl4822 composite powder and its effect on powder bed quality and powder spreadability in additive manufacturing.Advanced Engineering Materials, 2023 2200846.

[7]*Ma C L, Ge Q, YuanL H, *Gu D D, Dai D H, Setchi R, Wu M P, LiuY, LiD Y, Ma S, PengX, Fang Z Y. The development of laser powder bed fused nano-TiC/NiTi superelastic composites with hierarchically heterogeneous microstructure and considerable tensile recoverable strain.Composites Part B: Engineering, 2023, 250: 110457.

[8]*Ma C L, Gu D D, Setchi R, Dai D H, Wu M P, Ma S.A large compressive recoverable strain induced by heterogeneous microstructure in a Ni50.6Ti49.4 shape memory alloy via laser powder bed fusion and subsequent aging treatment.Journal of Alloys and Compounds, 2022, 918: 165620.

[9] *Ma C L, Wu M P, Dai D H, Xia M J. Stress-induced heterogeneous transformation and recoverable behavior of laser powder bed fused Ni-rich Ni50.6Ti49.4 alloys without post treatment.Journal of Alloys and Compounds, 2022, 905: 164212.

[10] Gao J, *Gu D D,Ma C L, Dai D H, Xi L X, Lin K J, Gao T, Zhu J H, Du Y X. Formation Process and Mechanical Deformation Behavior of a Novel Laser-Printed Compression-Induced Twisting-Compliant Mechanism.Engineering, 2022, 15: 133-142.

[11] *Gu D D,Ma C L, Dai D H, Yang J K, Zhang H M, Zhang H. Additively Manufacturing Enabled Hierarchical NiTi-based Shape Memory Alloys with High Strength and Toughness.Virtual and Physical Prototyping, 2021, 16: S19-S38.

[12]Ma C L, *Gu D D, Gao J, Chen W, Song Y J, Setchi R. Mechanical behavior of NiTi-based circular tube chiral structure manufactured by selective laser melting. SDM-2020 7th International Conference on Sustainable Design and Manufacturing, 9-11 September, Split, Croatia.

[13]Ma C L, *Gu D D, Dai D H, Yang J K, Zhang H, Guo M, Wang R, Gao J, Chen W, Song Y J. Tailored Pore Canal Characteristics and Compressive Deformation Behavior of Bionic Porous NiTi Shape Memory Alloy Prepared by Selective Laser Melting.Smart Materials and Structures, 2020, 29: 095001

[14]Ma C L, *Gu D D, Dai D H, Zhang H, Zhang H M,Yang J K, Guo M, Du Y X, Gao J. Microstructure evolution and high-temperature oxidation behaviour of selective laser melted TiC/TiAl composites.Surface & Coatings Technology, 2019, 375: 534-543

[15]Ma C L, *Gu D D, Lin K J, Dai D H, Xia M J, Yang J K, Wang H R. Selective laser melting additive manufacturing of cancer pagurus’s claw inspired bionic structures with high strength and toughness.Applied Surface Science, 2019, 469: 647-656.

[16]Ma C L, *Gu D D, Dai D H, Zhang H M, Du L, Zhang H. Development of interfacial stress during selective laser melting of TiC reinforced TiAl composites: Influence of geometric feature of reinforcement.Materials and Design, 2018, 157: 1–11;

[17]Ma C L, *Gu D D, Dai D H, Xia M J, Chen H Y. Selective growth of Ni4Ti3 precipitate variants induced by complicated cyclic stress during Laser additive manufacturing of NiTi-based composites.Materials Characterization,2018, 143: 191-196;

[18] *Gu D D,Ma C L. In-situ formation of Ni4Ti3 precipitate and its effect on pseudoelasticity in selective laser melting additive manufactured NiTi-based composites.Applied Surface Science, 2018, 441: 862-870;

[19] *Gu D D,Ma C L, Xia M J, Dai D H, Shi Q M. A Multiscale Understanding of the Thermodynamic and Kinetic Mechanisms of Laser Additive Manufacturing.Engineering, 2017, 3(5): 675-684;

[20]Ma C L, *Gu D D, Lin K J, Chen W H. Thermal behavior and formation mechanism of a typical micro-scale node-structure during selective laser melting of Ti-based porous structure.Journal of Materials Research, 2017, 32(8): 1506-1516;

[21]Ma C L, *Gu D D, Dai D H, Yu G Q, Xia M J, Chen H Y. Thermodynamic behaviour and formation mechanism of novel titanium carbide dendritic crystals within a molten pool of selective laser melting TiC/Ti–Ni composites.CrystEngComm, 2017, 19: 1089-1099;

[22]Ma C L, *Gu D D, Hong C, He B B, Chang K, Shi Q M. Formation Mechanism and Microstructural and Mechanical Properties of In-situ Ti-Ni-Based Composite Coatings by Laser Metal Deposition.Surface & Coatings Technology, 2016, 291: 43–53;

[23]Ma C L, *Gu D D, Dai D H, Chen W H, Chang F, Yuan P P, Shen Y F. Aluminum-based nanocomposites with hybrid reinforcements: Powder preparation by mechanical alloying and consolidation by selective laser melting.Journal of Materials Research, 2015, 30: 2816-2828.