代表性论文、论著
[1] C. Shen, K.D. Liss, Z. Pan, Z. Wang, X. Li, H. Li, Thermal cycling of Fe3Al based iron aluminide during the wire-arc additive manufacturing process: An in-situ neutron diffraction study. Intermetallics, 92 (2018) 101-107.
[2] C. Shen, Z. Pan, D. Cuiuri, S. van Duin, D. Luo, B. Dong, H. Li, Influences of postproduction heat treatment on Fe3Al based iron aluminide fabricated using the wire-arc additive manufacturing process. The International Journal of Advanced Manufacturing Technology, 97 (2018) 335-344.
[3] C. Shen, Z. Pan, Y. Ma, D. Cuiuri, H. Li, Fabrication of iron-rich Fe-Al intermetallics using the wire-arc additive manufacturing process. Additive Manufacturing, 7 (2015) 20-26.
[4] C. Shen, Z. Pan, D. Cuiuri, D. Ding, H. Li, Influences of deposition current and interpass temperature to the Fe3Al-based iron aluminide fabricated using wire-arc additive manufacturing process. The International Journal of Advanced Manufacturing Technology, 88 (2017) 2009-2018.
[5] C. Shen, Z. Pan, D. Cuiuri, J. Roberts, H. Li, Fabrication of Fe-FeAl functionally graded material using the wire-arc additive manufacturing process. Metallurgical and Materials Transactions B, 47 (2016) 763-772.
[6] C. Shen, Z. Pan, D. Cuiuri, B. Dong, H. Li, In-depth study of the mechanical properties for Fe3Al based iron aluminide fabricated using the wire-arc additive manufacturing process. Materials Science & Engineering A, 669 (2016) 118-126.
[7] C. Shen, Z. Pan, D. Ding, L. Yuan, N. Nie, Y. Wang, D. Luo, D. Cuiuri, S. van Duin, H. Li, The influence of post-production heat treatment on the multi-directional properties of nickel-aluminum bronze alloy fabricated using wire-arc additive manufacturing process, Additive Manufacturing, 22 (2018) 411-421.
[8] B. Dong, Z. Pan, C. Shen, Y. Ma, H. Li, Fabrication of copper-rich Cu-Al alloy using the wire-arc additive manufacturing process. Metallurgical and Materials Transactions B, 48 (2017) 3143-3151.
[9] Y. Ma, D. Cuiuri, C. Shen, H. Li, Z. Pan, Effect of interpass temperature on in-situ alloying and additive manufacturing of titanium aluminides using gas tungsten arc welding. Additive Manufacturing, 8 (2015) 71-77.
[10] Y. Ma, D. Cuiuri, H. Li, Z. Pan, C. Shen, The effect of postproduction heat treatment on -TiAl alloys produced by the GTAW-based additive manufacturing process. Materials Science & Engineering A, 657 (2016) 86-95.
[11] D. Ding, C. Shen, Z. Pan, D. Cuiuri, H. Li, N. Larkin, S. van Duin, Towards an automated robotic arc-welding-based additive manufacturing system from CAD to finished part. Computer-Aided Design, 73 (2016) 66-75.
[12] A.M. Paradowska, N. Larkin, H. Li, Z. Pan, C. Shen, M. Law, Neutron diffraction residual stress measurements of welds made with pulsed tandem gas metal arc welding (PT-GMAW). Powder Diffraction, 29 (2014) S24-S27.
[13] D. Ding, Z. Pan, S. van Duin, H. Li, C. Shen, Fabricating superior NiAl Bronze components through wire-arc additive manufacturing. Materials, 9 (2016) 652.
[14] J. Wang, Z. Pan, Y. Ma, Y. Lu, C. Shen, D. Cuiuri, H. Li, Characterization of wire arc additively manufactured titanium aluminide functionally graded material: Microstructure, mechanical properties and oxidation behavior. Materials Science & Engineering A, 734 (2018) 110-119.