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成果及论文


[1] S.C. Cao, X. Zhang, Y. Yuan, P. Wang, L. Zhang, N. Liu, Y. Liu, J. Lu, A constitutive model incorporating grain refinement strengthening on metallic alloys, Journal of Materials Science & Technology 88 (2021) 233-239.

[2] A.X.Y. Guo, L. Cheng, S. Zhan, S. Zhang, W. Xiong, Z. Wang, G. Wang, S. C. Cao*, Biomedical applications of the powder-based 3D printed titanium alloys: A review, Journal of Materials Science & Technology 125 (2022) 252-264.

[3] W. Xiong, A.X.Y. Guo, S. Zhan, C.-T. Liu, S. C. Cao*, Refractory high-entropy alloys: A focused review of preparation methods and properties, Journal of Materials Science & Technology 142 (2023) 196-215.

[4] S. C. Cao*, A.X.Y. Guo, G. Wu, Y. Wang, J. Lu, X. Zhang, A novel multiple impact model for predicting the residual stress state, Journal of Materials Research and Technology 23 (2023) 4779-4789.

[5] A.X.Y. Guo, B. Xiao, Q. Xiao, S. C. Cao*, Revisiting deformation anisotropy of ω-variants via microcompression of <110>β oriented Ti85Nb15 alloy, Journal of Materials Research and Technology 23 (2023) 3119-3125.

[6] S. Zhan, A.X.Y. Guo, N. Liu, S. C. Cao*, 3D Printing Soft Matters and Applications: A Review, International journal of molecular sciences 23(7) (2022).

[7] A.X.Y. Guo, Y. Wu, Z. Wang, Q. Xiao, S. C. Cao*, Strengthening and toughening of Ti–Nb films by adjusting internal stress, Vacuum 202 (2022) 111127.

[8] A.X.Y. Guo, Z. Lin, W. Xiong, S. Zhan, S. C. Cao*. Strengthening and Toughening of 3D Printing High Entropy Alloy. Journal of Material Sciences & Engineering 11 (03) 2022 013.

[9] A.X.Y. Guo, C. Geng, Z. Lin, S. C. Cao*. A Review of Research Progress on ω-phase in Titanium Alloys. Journal of Material Sciences & Engineering 11 (04) 2022 620.

[10] A.X.Y. Guo, W. Xiong, Q. Xiao, Z. Wang, S. C. Cao*, Thermal stability of Ti-Nb-Fe ternary nanocrystalline alloys related to grain boundary segregation, Vacuum 213, 112142 (2023).

[11] A.X.Y. Guo, Q. Xiao, Z. Wang, S. C. Cao*, Fabricated high-strength, low-elastic modulus biomedical Ti-24Nb-4Zr-8Sn alloy via powder metallurgy, Materials 2023 (16) 3845.

[12] S. C. Cao*, A.X.Y. Guo, H.Yang, A. Zhang, W. Li, J. Yang, S. Zhang. Discovering short-range ordering in a medium entropy alloy via intelligent big data. Nature communications. (Under review)

[13] S. Zhan, C.T. Liu, H. He*, S. C. Cao*, Materials for Sustainability: Metals and Alloys, Journal of Materials Science & Technology. (Under review)

[14] Zamani, M. R., Mirzadeh, H., Malekan, M., S. C. Cao*, & Yeh, J. W. Grain Growth in High-Entropy Alloys (HEAs): A Review. High Entropy Alloys & Materials, (2022)1-35.

[15] Wei Xiong, LJ Cheng, Amy X.Y. Guo, Shuai Zhan, Peter K. Liaw, Jien-Wei Yeh and Shan Cecilia Cao*. Recent Advances on Lightweight High-Entropy Alloys: Process, Design, and Applications. High Entropy Alloys & Materials. DOI 10.1007/s44210-023-00014-y.

[16] Shan Cecilia Cao, Xiaochun Zhang, Jian Lu, Yongli Wang, San-Qiang Shi, and Robert O. Ritchie. "Predicting surface deformation during mechanical attrition of metallic alloys." npj Computational Materials 5, no. 1 (2019): 1-15.

[17] Shan Cecilia Cao, Linli Zhu, Jiabin Liu, Ge Wu, Wenxuan Huang, Jian Lu*, Light-weight isometric-phase steels with superior Strength- hardness-ductility combination, Scripta Materialia, 154 (2018) 230–235.

[18] Shan Cecilia Cao, Jiabin Liu, Ling Li, Ming Dao, Jian Lu*, Robert O. Ritchie*. Nature-inspired Hierarchical Steels, Scientific Reports, 2018.

[19] Shan Cecilia Cao, Xiaochun Zhang, Linli Zhu, San-Qiang Shi, Jian Lu*, Comparison of two nano-structuring formation methods through making strong steels, Materials Today Communications, 2018.

[20] Yudong Wang, Shan Cecilia Cao*, Congcong Yuan, Jin Shi, Bin Yang, Yongnian Dai*, Division of the combustion stage using the pre-exponential factor and preparation of low-sulfur biomass fuels, Catalysis Today, 2018. 318, 66-72

[21] Bernoulli, Daniel, Shan Cecilia Cao, Jian Lu*, and Ming Dao*. Enhanced repeated frictional sliding properties in 304 stainless steel with a gradient nanostructured surface, Surface and Coatings Technology, 2018. 339, 14-19.

[22] Kang Y, Su F, Zhang Q, Liang F, Adair KR, Chen K, Xue D, Hayashi K, Shan Cecilia Cao, Yadegari H, Sun X. A Novel High Energy Density Rechargeable Hybrid Sodium–Air Cell with Acidic Electrolyte. ACS Applied Materials & Interfaces.2018 Jun 22.

[23] Zhou Dan, Xuechao Qiu, Feng Liang, Shan Cecilia Cao, Yaochun Yao, Xiaopeng Huang, Wenhui Ma, Bin Yang, and Yongnian Dai*. Comparison of the effects of FePO4 and FePO4· 2H2O as precursors on the electrochemical performances of LiFePO4/C, Ceramics International 43, no. 16, 2017: 13254-13263.

[24] Huang W, Kitchaev A, Dacek ST, Rong Z, Urban A, Shan Cecilia Cao, Luo C, Ceder G*. Finding and proving the exact ground state of a generalized Ising model by convex optimization and MAX-SAT. Physical Review B. 2016 Oct21;94(13):134424.

[25] Miao Wang, Rui Xu, LJ Cheng, Chiung Chih Lu, Shan Cecilia Cao. The present and future of sustainable materials:A review, Journal of Environmental Planning and Management .(Under review)

[26] Rui Xu, LJ Cheng, JY Chen, Shan Cecilia Cao. 3D Printing and Biomaterials for Biomedical Application:  A review, International journal of molecular sciences. (Under review)

[27] Rui Xu, LJ Cheng, JY Chen, W Xiong, S Zhan, Shan Cecilia Cao. High entropy materials for battery: A Review, International journal of molecular sciences. (Under review)

[28] S.C. Cao, A.X.Y. Guo, A. Zhang, H. Yang, S. Zhang, W. Li, C. Liu. Discovering short-range order in a medium-entropy alloy via data mining. Science. (Under review)

[29] A.X.Y. Guo, Q. Xiao, Z. Wang, S. C. Cao*, T.Y. Zhang. An ultra-strong, lightweight Titanium alloy with heterogeneous nano-structure, Journal of Materials Science & Technology. (Under review)

[30] A.X.Y. Guo, Z. Wang, S. C. Cao*, T.Y. Zhang. Ultra-strong and high compressive ductility Titanium alloys via constructing heterogeneous bimodal nanocrystalline-amorphous structure. Journal of Materials Science & Technology. (Under review)

[31] J. Wang, J. S, S. C. Cao*, W. J. Li, and Z Wang. A Highly Sensitive Self-assembled-nanoparticles e-Skin Sensor for Controlling. Advanced Materials (Under review)

[32] Liu, Lu, Tao Han, Shan Cecilia Cao*, Yanjie Liu, Jintao Shu, Chen Zheng, Tongxin Yu, Ziqiang Dong, and Yi Liu. "Enhanced wearing resistance of carbide reinforced FeCoNiCrMn high entropy alloy prepared by mechanical alloying and spark plasma sintering." Materials Today Communications 30 (2022): 103127.

[33] Yanbo Wanga, Jiaxiong Zhua, Chena, Xun Guo, Rong Zhang, Hu Hong, Yue Hou, Ze Chen, Guojin Liang, Shan Cecilia Cao, and Chunyi Zhi, Spider silk-inspired binder design for flexible lithium-ion battery with high durability (Under review)

[34] Yuwei Zhao, Hu Hong, Shan Cecilia Cao, Hongfei Li, and Chunyi Zhi, Zn-rejuvenated and SEI-regulated Additive in Zinc Metal Battery via the Iodine Post-functionalized Zeolitic Imidazolate Framework-90 (Under review)

 

* 代表通讯作者

 

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