（一）标准

1. 曹昱澎，谈建平，包陈，等, T/CNIDA 013-2023 重水堆压力管先漏后破分析方法, 2023.

2. 蔡力勋，包陈，韩光照，等，T/CSTM 00278-2021 金属材料强度、应力应变关系的圆环压缩试验方法，2020.

3. 蔡力勋，包陈，陈辉，等，GB/T 37782-2019金属材料 压入试验方法 强度、硬度和应力-应变关系的测定，2019.

4. 刘涛，蔡力勋，高怡斐，包陈，方健，等，GB/T 21143-2014 金属材料准静态断裂韧度的统一试验方法，2015.

（二）论文 

1. Cui Guangshun, Sun Jianhua, Bao Chen*, Li Yilei, Luo Jiacheng. Experimental and numerical investigation of dynamic fracture behavior in reactor pressure vessel steel under varying loading rates and geometric constraints. Engineering Fracture Mechanics, 2025.

2. Ding Wenjing, Du Kaikai, Bao Chen*. Investigation on the method to estimate fracture properties of semi-elliptical surface cracked plate under three-point bending. Engineering Fracture Mechanics, 2025, 320: 111062.

3. Xu Xikai, Wu Zhiyi, Bao Chen*, Cao Yupeng, Zhao Guannan. Investigation of the tensile fracture behavior and failure criteria of domestic Zr-2.5Nb alloy under different stress triaxiality conditions.  Engineering Fracture Mechanics, 2025, 318: 110991.

4. Qi Shuang, An Yinghui, Ding Wenjing, Huang Ping, Fan Minyu, Fang Kuiyuan, Bao Chen*, Cai Kexin. Specimen reconstitution method for the assessment of fracture properties of reactor pressure vessel steels. Engineering Fracture Mechanics, 2024, 312: 110610.

5. Xu Xikai, Bao Chen*. The method for the estimation of fracture toughness of thin-walled metallic tube considering the effect of crack orientation. Engineering Fracture Mechanics, 2024, 303: 110107.

6. Wu Yuanjun, Huang Maobo, He Guangwei, Bao Chen*.  Quantification of crack tip constraint effect based on the critical distance. Fatigue & Fracture of Engineering Materials & Structures, 2024, 47:2411-2426.

7. Sun Jianhua, Guangshun Cui, Yilei Li,Bao Chen*. Investigation on the dynamic fracture behavior of A508-III steel based on Johnson-Cook model. International Journal of Fracture, 2023, 243(1): 105-121.

8. Xu Xikai, Bao Chen*, Liu Xiao, Wang Li. A unified method to estimate J-resistance curve of thin-walled metallic tube containing axial cracks. Theoretical and Applied Fracture Mechanics, 2023,123:103730.

9. He Guangwei, Cai Lixun*, Bao Chen*. Semi-analytical models for J-integral and load–displacement relation of surface-cracked body and their applications for J-R curves. Theoretical and Applied Fracture Mechanics, 2023, 124: 103789.

10. He Guangwei, Cai Lixun*, Bao Chen*. Evaluation of the J-R curve for surface-cracked round bar by a semi-analytical method. Archive of Applied Mechanics, 2023, 93: 1-16.
    

11. Wu Yuanjun, Bao Chen*, Cai Lixun, Wang Kaiqing, Liu Xiao. Estimation of Fracture Toughness for A508-III Steel in Ductile-to-Brittle Transition Region Using a Strain-Energy-Density-Based Fracture Failure Model. Acta Mechanica Solida Sinica, 2022,35: 834-841. 

12. Cui Guangshun, Bao Chen*, Mengxue Zhang, Xu Zhang. Effects of thermal aging on mechanical properties and microstructures of an interstitial high entropy alloy with ultrasonic surface mechanical attrition treatment. Materials Science & Engineering A, 2022, 838: 142755.

13. Han Guangzhao, Cai Lixun, Bao Chen, Liang Bo, Lyu Yang, Huang Maobo, Liu Xiaokun. Novel Ring Compression Test Method to Determine the Stress-Strain Relations and Mechanical Properties of Metallic Materials. Chinese Journal of Mechanical Engineering, 2021, 34:109.

14. Bao Chen*, Sun Yongduo, Wu Yuanjun, Wang Li, He Guangwei. Fracture properties and crack tip constraint quantification of 321/690 dissimilar metal girth welded joints by using miniature SENB specimens. Nuclear Engineering and Technology, 2020, 53(6): 1924-1930.

15. Simiao Yu，Lixun Cai，Di Yao，Chen Bao. Critical ductile fracture criterion based on first principal stress and stress triaxiality. Theoretical & Applied Fracture Mechanics, 2020, 109, 102696.

16. Hui Chen，Lixun Cai，Chen Bao. A novel model for determining tensile properties and hardness of steels by spherical indentations. Strain, 2020, 56(5), e12365.

17. Wei Lian-feng, Bao Chen*, Wang Shi-zhong, Zheng Yong, Zhou Meng-bin. Low cycle fatigue properties of hydrogenated welding sheets of Zr-Sn-Nb alloy using funnel-shaped flat specimens. Nuclear Engineering and Technology, 2020,52(8): 1724-1731.

18. G.W. He, C. Bao*, L.X. Cai*. Study on uniform parameters characterizing the crack-tip constraint effect of fracture toughness. Engineering Fracture Mechanics, 2019,222,106706.

19. G.W. He, C. Bao*, L.X. Cai*, Y.J. Wu. Estimation of J−R Curves for Small-Sized COEC Specimens and Its Application Considering Crack-Tip Constraints. Acta Mechanica Solida Sinica, 2019,32: 216-276.

20. Qi S, Cai L X, Bao C*, et al. Analytical theory for fatigue crack propagation rates of mixed-mode I–II cracks and its application[J]. International Journal of Fatigue, 2019, 119: 150-159. 

21. Qi S, Cai L X, Bao C*, et al. The prediction models for fatigue crack propagation rates of mixed-mode I-II cracks[J]. Engineering Fracture Mechanics, 2019, 205: 218-228.

22. Chen H, Cai L X, Bao C*. Equivalent-energy indentation method to predict the tensile properties of light alloys[J]. Materials & Design, 2019, 162:322-330.
    

23. Chen Bao*,  Li-xun Cai, Guang-wei He, Yuan-jun Wu. A method to evaluate ductile fracture toughness based on load separation principle. Fatigue & Fracture of Engineering Materials & Structures,2018:42(1): 178-186.

24. Bao Chen*, Cai Li-xun, Shi Kai-kai. Prediction of fatigue crack growth rate for small-sized CIET specimens based on low cycle fatigue properties. Chinese Journal of Aeronautics, 2018, 31(4): 740-748.

25.  Bao C*, Cai L X, He G W, et al. Normalization method for evaluating J-resistance curves of small-sized CIET specimen and crack front constraints. International Journal of Solids and Structures, 2016, 94: 60-75.

26. Yao D, Cai L, Bao C. A new fracture criterion for ductile materials based on a finite element aided testing method[J]. Materials Science and Engineering: A, 2016, 673: 633-647.

27. Yao D, Cai LX, Bao C. A new approach on necking constitutive relationships of ductile materials at elevated temperatures. Chinese Journal of Aeronautics, 2016, 29(6): 1626-1634.

28.  Bao C*, Cai L X, Dan C. Estimation of fatigue crack growth behavior for small-sized C-shaped inside edge-notched tension (CIET) specimen using compliance technique. International Journal of Fatigue, 2015, 81: 202-212.

29. Bao C*, Cai L, Shi K, et al. Improved normalization method for ductile fracture toughness determination based on dimensionless load separation principle. Acta Mechanica Solida Sinica, 2015, 28(2): 168-181.

30. Chen Bao*, Li-xun Cai, Kai-kai Shi, Yao Yao. Estimation of J-resistance curves for CT specimen based on unloading compliance method and CMOD data. Journal of Testing and Evaluation, 2015,43(3):517-527.

31. Shi KK, Cai LX, Bao C, Wu SC, Chen L. Structural fatigue crack growth on a representative volume element under cyclic strain behavior. International Journal of Fatigue. 2015, 74:1-6.

32. Shi KK, Cai LX, Bao C. Crack Growth Rate Model under Constant Cyclic Loading and Effect of Different Singularity Fields. Procedia Materials Science. 2014, 3:1566-1572.

33.  Bao Chen*, Lixun Cai. Investigation on Spb method based on nondimensional load separation principle for SEB and CT specimens. Applied Mechanics and Materials, 2012, 117-119: 480-488.

34. Yao Yao, Cai Lixun, Bao Chen, Jiang Han. The fined COD transform formula for CT specimens to investigate material fracture toughness. Applied Mechanics and Materials, 2012, 188: 11-16.

35. Yao Bo, Lixun Cai, Bao Chen. The sharp indentation for identifying consititutive relationship of metallic materials. Applied Mechanics and Materials, 2012, 117-119: 101-107.

36. Shi Kaikai, Lixun Cai, Bao Chen, Yao Yao. The dimensionless load separation method used for fracture toughness test and its application. Applied Mechanics and Materials, 2012, 117-119: 460-466.

37. Chen Long, Cai Lixun, Huang Xuewei, Bao Chen. On numerical simulation method and its applications for fatigue crack growth. Applied Mechanics and Materials, 2012, 117-119: 180-185.

38. Shi, Kaikai ; Cai, Li-Xun; Bao, Chen; Yao, Yao. Dimensionless load separation theory using SE(B) specimen and software development. TELKOMNIKA Indonesian Journal of Electrical Engineering, 2012,10( 8): 2261-2266.

39. Bao Chen*, Cai Lixun. Investigation on compliance rotation correction for compact tensile specimen in unloading compliance method. Acta Mechanica Solida Sinica, 2011, 24(2): 144-152.

40. 吴志懿，曹昱澎，赵冠楠，徐习凯，包陈*. 试样构形和裂纹取向对Zr-2.5Nb合金压力管断裂韧性的影响研究，机械工程学报, 2025.

41. 巫元俊，徐习凯，包陈*，蔡力勋. 考虑几何尺寸影响的RPV钢韧脆转变实验研究，力学学报，2023, 55(10): 2367-2372.

42. 张梦雪,包 陈*,吴志懿. 体外脱钙对牛股骨松质骨拉伸和断裂性能影响的实验研究, 中国测试，2025,2: 46-54.

43. 杜开开，包陈*，何广伟.弯曲载荷下含半椭圆表面裂纹平板疲劳裂纹扩展试验方法 研究. 机械工程学报，2024,60(24):153-162.

44. 崔光顺，包陈*，李一磊，孙建华，杜开开. 考虑速率和几何尺寸影响的国产A508-III钢锻炼行为实验研究. 力学学报，2022, 54(7): 1-12.

45. 李志浩，包陈*，何广伟. 含双边轴向裂纹N18锆合金管的蠕变裂纹扩展行为研究.核动力工程，2020,5:53-59.

46. 王博，包陈*，魏连峰，何广伟.氢化物对锆合金薄板焊缝断裂行为的影响研究，机械工程学报，2021, 57(20): 133-140.

47. 祁爽，蔡力勋，包陈，刘晓坤. 30Cr2Ni4MoV转子钢II型裂纹的疲劳扩展行为, 机械工程学报, 2020.

48. 刘肖，王理，包陈，王恺晴，赵宇翔，王浩，徐祺. 含轴向对称裂纹锆合金包壳管断裂行为.机械工程学报, 2019, 16: 85-90.

49. 于思淼, 蔡力勋, 姚迪, 包陈, 陈辉, 彭云强, 韩光照. 准静态条件下金属材料的临界断裂准则研究, 力学学报，2018, 50(5): 1063-1080.

50. 刘肖，王理，包陈，王浩，马娜. TA16传热管的断裂韧度测试方法研究. 原子能科学与技术, 2018, 52(3): 427-433.

51. 巫元俊，包陈*，何广伟，蔡力勋. 用于J阻力曲线测试的载荷分离直接标定法. 航空学报, 2017, 38(10): 164-170.

52. 何广伟, 包陈*, 蔡力勋, 赵兴华. COEC微小试样用于延性断裂行为评定的规则化法研究[J]. 机械工程学报, 2017,53(20): 61-68.

53. 包陈，蔡力勋，但晨. 考虑裂尖约束效应的小尺寸CIET试样延性断裂行为.机械工程学报, 2017, 53(02):34-44.

54. 包陈，蔡力勋，石凯凯，但晨，姚瑶，金蕾. 金属材料准静态断裂性能标准测试技术研究进展，机械工程学报,2016,52(8):76-89.

55. 彭云强, 蔡力勋, 包陈, 姚迪. 基于材料全程本构关系对延性断裂韧性的数值模拟方法与应用. 工程力学, 2016,33(5):11-17.

56. 赵兴华，蔡力勋，包陈，江志华.基于漏斗试样的C250钢高温扭转低周疲劳行为.航空学报,2016,37(2):617-625.

57. 赵兴华，蔡力勋，包陈. CRO 试样的疲劳裂纹扩展行为试验方法研究. 工程力学, 2016,33(11): 20-28.

58. 陈辉, 蔡力勋, 包陈. 双锥度压入的FAT 迭代法获取材料的力学性能. 核动力工程, 2015,36(5): 101-104.

59. 祁爽, 蔡力勋, 包陈, 等. 基于应力三轴度的材料颈缩和破断行为分析. 机械强度, 2015,37(6): 1152-1158.

60. 祁爽,蔡力勋,包陈,姚迪.基于等效全程单轴本构关系的应力三轴度分析.工程力学, 2015, 32(s1): 27-32.

61. 但晨, 蔡力勋, 包陈. C形环小试样疲劳裂纹扩展试验方法与应用. 工程力学, 2015,32(12):27-32.

62. 但晨, 蔡力勋, 包陈, 吴海利. 用于断裂韧性测试的C形环小试样规则化方法与应用. 机械工程学报, 2015,51(14):54-65.

63. 赵兴华，蔡力勋，包陈. 含径向双边裂纹圆环小试样的疲劳裂纹扩展试验方法. 中国测试, 2015, 41(7): 1-5.
    

64. 石凯凯，蔡力勋，包陈，预测疲劳裂纹扩展的多种理论模型研究，机械工程学报，2014，50(18):50-58

65. 姚瑶, 蔡力勋, 包陈, 石凯凯. 基于SENT试样获取材料断裂韧度的载荷分离法研究. 机械工程学报. 2014,50(10):48-57.

66.  姚瑶, 蔡力勋, 包陈, 石凯凯, 吴海莉，基于直通型CT试样测试方法的断裂韧度研究，航空材料学报, 2014, 34 (6): 67-74

67. 贾琦，蔡力勋，包陈，考虑循环塑性修正的薄片材料低周疲劳试验方法[J]，工程力学,2014,31(1):218~223

68.  陈辉，蔡力勋，姚迪，包陈,基于小尺寸材料试验与有限元分析的耦合方法获取材料力学性能,机械强度，2014，36(2):187~192

69. 但晨，蔡力勋，包陈，姚瑶，平面应变断裂韧度评定中临界载荷PQ研究,中国测试,2014，40(1):21-24.

70. 姚博，蔡力勋，包陈，获取材料本构关系和硬度的压入法研究, 中国测试，2014,40(2):13-18.

71. 彭云强, 蔡力勋, 包陈, 等. GTN 模型参数标定方法与应用. 应用数学和力学, 2014, 35(s):75-78.

72. 包陈, 蔡力勋, 石凯凯. 无量纲载荷分离法在延性断裂韧性测定中的应用. 固体力学学报, 2013, 34(1): 20-30.

73. 姚博，蔡力勋，包陈.基于锥形压入的材料力学性能测试方法研究. 航空学报, 2013, 34(8):1874-1883.

74. 姚博，蔡力勋，包陈. 基于70.3度圆锥形压头的材料压入测试方法研究. 工程力学, 2013, 30(6): 30-35.

75. 姚瑶，蔡力勋，包陈. 用于弯曲型试样断裂韧性计算的COD转换公式精解. 中国测试, 2013, 39(1): 25-30.

76. 陈辉，蔡力勋，姚迪，包陈. TF方法获取异型试样性能参数及其应用. 西南交通大学学报，2013，48(s):123-126.

77. 石凯凯, 蔡力勋, 包陈, 姚瑶. 断裂韧性测试的量纲一载荷分离方法及应用. 浙江大学学报(工学版), 2012, 46(7): 1201-1206.

78. 石凯凯, 蔡力勋, 包陈. 弯曲型单边裂纹试样的转动修正方法研究. 机械强度, 2012, 34(2):250-255.

79. 包陈，蔡力勋, CTOD试验方法与转子材料的延性断裂性能. 机械强度,2012,162(4):573-577.
    

80. 蔡力勋，贾琦，包陈，周向裂纹圆棒试样的断裂韧性测试方法研究，中国测试,2012,38(3):9-12.

81. 包陈, 蔡力勋, 石凯凯. 直通型CT试样COD弹塑性换算研究. 北京科技大学学报, 2011, 33(7): 863-867.

82. 蔡力勋, 包陈. 用于延性断裂韧性测试的载荷分离方法与应用. 北京科技大学学报, 2011, 33(7): 868-875.

83. 黄学伟, 蔡力勋, 包陈, 陈龙. 基于低周疲劳损伤的疲劳裂纹扩展行为数值模拟新方法. 工程力学, 2011, 28(10): 202-208.