成天寶

人物經歷

教育背景

• 2014.09-2016.06，北京大學，工學院力學系，交流
  
• 2011.09-2016.06，重慶大學，工程力學專業，博士
  
• 2007.09-2011.06，重慶大學，工程力學專業，學士
  

工作履歷

• 2019.05-0000.00，重慶大學，航空航天學院，副研究員、博導
  
• 2018.11-2019.05，重慶大學，航空航天學院，副研究員
  
• 2016.06-2018.11，北京理工大學，先進結構技術研究院，博後
  

研究領域

• 固體材料高溫斷裂力學
  
• 陶瓷材料抗熱衝擊性能
  
• 超高溫極端環境下材料力學性能實驗研究及儀器設備研製
  

項目情況

1. 國家自然科學基金青年科學基金項目，11802019，氮化矽陶瓷高溫表界面能理論研究與斷裂機理分析，2019.01-2021.12，30萬元，主持
   
2. 重慶市自然科學基金面上項目，cstc2019jcyj-msxmX0038，超高溫極端環境下氮化矽陶瓷斷裂性能研究及微觀結構設計，2019.07-2021.06，10萬元，主持
   
3. 重慶市人社局出站留（來）渝博士後擇優資助項目，2018LY48，高超熱防護材料超高溫極端環境下力學性能評價，2018.12-2021.12，15萬元，主持
   
4. 中央高校基本科研業務費學院研究專項項目，2019CDXYHK0001，氮化矽陶瓷高溫穿沿晶行為研究，2019.01-2020.11，5.25萬元，主持
   
5. 國家人社部博士後創新人才支持計畫，BX201600016，超高溫感應加熱力學性能試驗機研製及兩類典型熱防護材料的性能表征，2016.08-2018.11，60萬元，主持
   
6. 中國博士後科學基金面上項目（一等資助），2016M600047，氮化矽陶瓷高溫斷裂性能定量化研究，2016.11-2018.11，8萬元，主持
   
7. 航天三院301所國家重大科技專項xxxx工程二級契約，GFZX010501-2017B205，xxx材料高溫力學性能實驗評價，2018.06-2018.11，30萬元，主持
   
8. 航天三院301所技術服務，20160096，xxx材料力學和熱物理性能測試，2016.08-2017.10，75萬元，主持
   
9. 國家自然科學基金重大科研儀器研製項目（自由申請），11227801，超高溫極端環境下材料性能測試設備研製，2013.01-2017.12，900萬元，參與
   
10. 國家自然科學基金重大科研儀器研製項目（自由申請），11727802，複雜熱衝擊環境下超高溫材料抗熱衝擊性能的高通量測試儀器研製，2018.01-2022.12，900萬元，參與
    
11. 軍委科技委基礎加強（原國防973），2017-JCJQ-ZD-035，xxx結構設計與製造一體化基礎研究，2018.01-2022.12，4600萬元，參與
    
12. 工信部"兩機"專項，2017-VI-0020-0093，xxx設計、製備與考核，2018.08-2022.08，項目研究經費3280萬元，條保建設經費4009萬元，參與
    

學術成果

1. T. B. Cheng, Y. Tao, W. G. Li, L. M. Chen, D. N. Fang, and Y. Z. Yang, Compressive Properties of Chemical Vapor Deposited Zinc Sulfide at High Temperatures, Journal of the Ceramic Society of Japan, Vol. 127, No. 8, pp. 527–530, 2019.
   
2. T. B. Cheng*, R. B. Zhang*, Y. M. Pei*, R. J. He, D. N. Fang, and Y. Z. Yang, Flexural Properties of Carbon-Carbon Composites at Temperatures up to 2600°C, Materials Research Express, Vol. 6, No. 8, Article ID 085629, 5 pages, 2019.
   
3. T. B. Cheng*, D. N. Fang, and Y. Z. Yang, The Temperature-Dependent Ideal Shear Strength of Solid Single Crystals, Journal of Applied Mechanics, Vol. 85, No. 3, Article ID 031005, 5 pages, 2018.
   
4. T. B. Cheng*, D. N. Fang, and Y. Z. Yang, The Temperature Dependence of Grain Boundary Free Energy of Solids, Journal of Applied Physics, Vol. 123, No. 8, Article ID 085902, 5 pages, 2018.
   
5. T. B. Cheng*, D. N. Fang, and Y. Z. Yang, Modeling of the Temperature-Dependent Ideal Shear Strength of Solid Single Crystals, Intermetallics, Vol. 93, pp. 299–302, 2018.
   
6. T. B. Cheng*, D. N. Fang, and Y. Z. Yang, The Temperature-Dependent Surface Energy of Ceramic Single Crystals, Journal of the American Ceramic Society, Vol. 100, No. 4, pp. 1598–1605, 2017.
   
7. T. B. Cheng*, D. N. Fang, and Y. Z. Yang, A Temperature-Dependent Surface Free Energy Model for Solid Single Crystals, Applied Surface Science, Vol. 393, pp. 364–368, 2017.
   
8. T. B. Cheng, Y. B. Ma, H. M. Li, D. N. Fang, and Y. Z. Yang, Flexural Properties of Chemical Vapor Deposited Zinc Sulfide at High Temperatures, Journal of Alloys and Compounds, Vol. 729C, pp. 1086–1092, 2017.
   
9. T. B. Cheng, W. G. Li, R. B. Zhang, and D. N. Fang, Compressive Strength and Failure Mechanism of Chemical Vapor Deposited Zinc Sulfide from Room Temperature to 600°C, High Temperatures-High Pressures, Vol. 46, pp. 133–140, 2017.
   
10. T. B. Cheng, W. G. Li, Z. L. Qu, W. B. Wen, and D. N. Fang, Thermal Shock Resistance of Chemical Vapour Deposited Zinc Sulfide at Elevated Temperatures, Transactions of the Indian Ceramic Society, Vol. 75, No. 4, pp. 215–219, 2016.
    
11. T. B. Chengand W. G. Li, The Temperature-Dependent Ideal Tensile Strength of ZrB2, HfB2, and TiB2, Journal of the American Ceramic Society, Vol. 98, No. 1, pp. 190–196, 2015.
    
12. T. B. Cheng, W. G. Li, R. B. Zhang, and D. N. Fang, The Direct Uniaxial Tensile Strength of Chemical Vapor Deposited Zinc Sulfide from Room Temperature to 600°C, Materials Letters, Vol. 158, pp. 140–142, 2015.
    
13. T. B. Cheng, W. G. Li, Y. S. Shi, W. Lu, and D. N. Fang, Effects of Mechanical Boundary Conditions on Thermal Shock Resistance of Ultra-High Temperature Ceramics, Applied Mathematics and Mechanics (English Edition), Vol. 36, No. 2, pp. 201–210, 2015.
    
14. T. B. Cheng, W. G. Li, Y. S. Shi, and W. Lu, Effects of In-Plane Geometric Shapes on Thermal Shock Resistance of Ultra-High Temperature Ceramic Components, Transactions of the Indian Ceramic Society, Vol. 74, No. 1, pp. 6–10, 2015.
    
15. T. B. Cheng, W. G. Li, W. Lu, Y. S. Shi, and D. N. Fang, Thermal Shock Resistance of Ultra-High-Temperature Ceramic Thermal Protection System, Journal of Spacecraft and Rockets, Vol. 51, No. 3, pp. 986–990, 2014.
    
16. T. B. Cheng, W. G. Li, C. Z. Zhang, and D. N. Fang, Unified Thermal Shock Resistance of Ultra-High Temperature Ceramics under Different Thermal Environments, Journal of Thermal Stresses, Vol. 37, No. 1, pp. 14–33, 2014.
    
17. T. B. Cheng, W. G. Li, and D. N. Fang, Modeling of the Temperature-Dependent Ideal Tensile Strength of Solids, Physica Scripta, Vol. 89, No. 8, Article ID 085803, 16 pages, 2014.
    
18. T. B. Cheng, W. G. Li, W. Lu, and Y. S. Shi, Heat Transfer and Failure Mode Analyses of Ultrahigh-Temperature Ceramic Thermal Protection System of Hypersonic Vehicles, Mathematical Problems in Engineering, Vol. 2014, Article ID 412718, 11 pages, 2014.
    
19. T. B. Cheng, W. G. Li, Q. M. Li, H. B. Kou, and D. N. Fang, The Bending Strength of Bulk Polycrystalline Alumina from Room Temperature to Melting Point, High Temperatures-High Pressures, Vol. 43, No. 4, pp. 285–295, 2014.
    
20. T. B. Cheng, W. G. Li, and D. N. Fang, Thermal Shock Resistance of Ultra-High-Temperature Ceramics under Aerodynamic Thermal Environments, AIAA Journal, Vol. 51, No. 4, pp. 840–848, 2013.