Acta Metall Sin  1997, Vol. 33 Issue (2): 187-197    DOI:

Current Issue | Archive | Adv Search |

PHYSICAL FUNDAMENTALS OF MESOMECHANICS OF PLASTIC DEFORMATION AND FRACTURE OF SOLIDS

V.E.Panin(The Institute of Strength Physics and Materials Sciences; Russian Academy of Sciences;Siberian Branch; Tomsk; 634048; Russia)

V.E.Panin(The Institute of Strength Physics and Materials Sciences; Russian Academy of Sciences;Siberian Branch; Tomsk; 634048; Russia). PHYSICAL FUNDAMENTALS OF MESOMECHANICS OF PLASTIC DEFORMATION AND FRACTURE OF SOLIDS. Acta Metall Sin, 1997, 33(2): 187-197.

Abstract References Related Articles Recommended Metrics Download:  PDF(4379KB)  Export:  BibTeX | EndNote (RIS)       Abstract  The research review on plastic deformation and fracture of solids based on phvsicalmesomechanics is presented. A solid under loading is considered in physicalmesomechanics as multilevel self-consistent system. where the plastic flows atmicro-meso- and macrolevels are natrually interrelated according to the principle ofscaIe invarlance.Bulk mesovolumes are moved at the mesoscale level according toscheme "shear+rotation". Plastic deformation and fracture of solids are considered astwo stages of the same process. Key words:  mesomechanics      plastic deformation      fracturel      Received:  18 February 1997      Service E-mail this article Add to citation manager E-mail Alert RSS （） Articles by authors URL:  https://www.ams.org.cn/EN/     OR     https://www.ams.org.cn/EN/Y1997/V33/I2/187 1 V.E.Panin, Y.V.Grinyaev, T.F.Elsukova and A.G.Ivanchin, Izv. VUZOV Fisika (6) (1982) 5. 2 V.E.Panin, V.A.Likhachev and Y.V.Grinyaev, Deformation Structural Levels of Solids. (Nauka,Novosibirsk, 1985) p.229. 3 V.E.Panin. V.E.Egorushkin, Yu.A. Chon and T.F.Elsukova, Izv. VUZOP Fisika (12) (1989) 5. 4 Y.V.Grinyaev and N.V.Chertova, Izv. VUZOV. FisikQ (2) (1990) 36. 5 V.E.Panin, Izv. SO AN USSR. Ser. Techn. Sciences 3 (1987) 87. 6 V.E.Panin, Y.V.Grinyaev, V.I.Danilov et al., Structural Levels of Plastic Dekrmation and of Fracture(Nauka, Novosibirsk, 1990) p.225. 7 V.E.Panin, T.F.Elsukova, E.N.Novoselova and V.E.Egorushkin, DAN USSR 310 (l99O) 78. 8 V.E.Egorushkin, Izv. VUZOV. Fizika (4) (1992) 19 9 V.E.Panin and T.F.Elsukova, Synergrtics and FaIikue Fracture of Metals, ed. V. Ivanova (Nauka,Moscow, 1989) p.248. 10 V.E.Panin, Y.V.Grinyaev, V.E.Egorushkin et al., Izv. VUZO V. Fizika (1) (1987) 36. 11 V.E.Panin, T.F.Elsukova, M.K.Eliseeva and Yu.V. Griniaev, Surkce Physics, Chemistry, Mechanics5 (1983) 138. 12 Yu.V.Grinjaev, V.E.Panin, Izv. VUZOV. Ficika (8) (1978) 95. 13 V.E.Panin, Yu.V.Grinyaev et al., DAN USSR 309 (1989) 356 14 V.E.Panin, Izv. VUZOV Ficika (4) (1992) 5. 15 T.F.Elsukova and V.E.Panin, Metals, 2 (1992) 73 16 V.E.Panin, Izv. VUZOV. FisIka (2) (1990) 4. 17 V.E.Panin and K.V.Frolov, The New Physical and Mechanical Methods of Investigation of Materials un-der Loading, ed. V.E.Panin (Tomsk University Press, Tomsk, 1990) p.332. 18 P.V.Makarov, The New Physical and Mechanical Methods of Invesigation of Materials under Loading,ed. V.E.Panin (Tomsk University Press, Tomsk, 1990) p.332. 19 V.E.Panin, Abstracts ofthe frst European East-West Symp. on Materials and Processes (Helsinki1990). 20 V.E.Panin and S.P.Efimenko, Abstracts of the 2nd European Con.f o.f Advanced Materials andProcesses (London, 1991 ) p.288. 21 V.E.Panin, V.E.Egorushkin, T.F.Elsukova and O.V.Veselova, DAN USSR 316 (1990) 1130 22 V.E.Panin, V.E.Egorushkin, T.F.Elsukova and O.V.Veselova, The New Physical and Mechanical Meth-ods ofInvestbotion of MaterJbls under Lnading, ed. V.E.Panin (Tomsk University Press, Tomsk, 1990)P.332. 23 V.E.Panin, T.F.Elsukova, E.M.NovoseIova and V.E.Egorushkin, DAN USSR 276 (1989) 630. 24 K.P.Zhukova, T.F.Elsukova, V.E.Panin and Y.N.Rudenko, Izv. VUZO V. Fisika (4) (1988) 13. 25 V.E.Panin, T.F.Elsukova, E.M.Novoselova and V.E.Egorushikin, DAN USSR 310 (1990) 78. 26 V.E.Panin, L.B.Zuev, V.I.DaniIov and N.M.Mnikh, FMM 66 (1988) 1005. 27 V.E.Panin, L.B.Zuev, V.I.Danilov and N.M.Mnikh, DAN USSR 308 (1989) 1375. 28 V.E.Panin, L.B.Zuev, V.I.Danilov and N.M.Mnikh, FMM 6 (1990) 189. 29 L.B.Zuev, V.E.Panin, V.I.Danilov, N.M.Mnikh and N.V.Peker, DAN USSR 317 (1991) 1386. 30 V.I.Danilov, L.B.Zuev, N.M.Mnikh, V.E.Panin and L.V.Shershova, FMM 3 (1991) 188. 31 V.E.Panin, L.B.Zuev, V.I.Danilov, P.V.Makarov, V.E.Egorushkin, B.B.Gorbatenko, Y.Hida andS.Yoshida, Method and Apporatus for Nondestructive Testing of the Mechanical Behavior ofSolid StateObkct under Loading, RUS Patent, N93002731, Moscow, Russia. 32 V.E.Panin, Y.I.Meshcheryakov, T.F.Elsukova, A.K.Dyvakov, S.G.Psakhie and N.M.Myshlyaev, I:v.VUZO V. Fizka (2) (1990) 107. 33 V.E.Panin, PhySical Mesomechanics and Computer Aided Design of Materials, (Nauku SO, Novosibirsk.v.l, (1995) p.297 and v.2, (1995) p.320. 34 V.E.Panin, Physical Mesomechanics of heterogeneous Medta and Compoter-Aided DesoignofMaterials (Cambridge Interscience Publishing, Cambridge, 1996) p.450. 35 V.E.Panin, Destw 0fNew Materials and Strengthening (Cambridge Interscience Publishing, Cambridge,1996) p.140. 36 V.E.Panin, Jpe. J. Appl. Phys. 9 (1995) 64. 37 V.E.Panin, A.I.Slosman and N.A.Kolesova, FMM 2 (1996) 82. 38 V.E.Panin and T.F.Elsukova, Doclady RAN 5 (1996) 247,617. 39 V.E.Panin and T.F.Elsukova, Izv. VUZO V. Ficika 39 (6) (1996) 40. 40 V.E.Panin, Izv. VUZOV. Fisika 38 (11) (1995) 6. 41 P.V.Makarov, O.I.Cherepanov and V.N.Demidov- I:v. VUZO V. Ficika 38 (11) (1995) 26. 42 S.G.Psakhie, Ya. Horie, S.Yu. Korostelev, A.Yu. Smolin, A.I.Dmitriev, E.V.Shilko and S.V.Alexeev,Izv. VUZOV Fizika 38 (11) (1995) 58. 43 Yu.A.Chon and V.E.Panin, Sold State Phys. 38 (1996) 1767. 44 V.E.Panin, S.V.Panin and A.I.Mamaev, Doclady RAN 1 (1996) 350. 45 V.E.Panin, The Abstracts of Int. Conf" Mathematical Methods in Phystcs, Mechanics andMesomechanics of Fracture", (1996) P. 135.6 [1] ZHANG Haifeng, YAN Haile, FANG Feng, JIA Nan. Molecular Dynamic Simulations of Deformation Mechanisms for FeMnCoCrNi High-Entropy Alloy Bicrystal Micropillars[J]. 金属学报, 2023, 59(8): 1051-1064. [2] WAN Tao, CHENG Zhao, LU Lei. Effect of Component Proportion on Mechanical Behaviors of Laminated Nanotwinned Cu[J]. 金属学报, 2023, 59(4): 567-576. [3] GUO Xiangru, SHEN Junjie. Modelling of the Plastic Behavior of Cu Crystal with Twinning-Induced Softening and Strengthening Effects[J]. 金属学报, 2022, 58(3): 375-384. [4] REN Shaofei, ZHANG Jianyang, ZHANG Xinfang, SUN Mingyue, XU Bin, CUI Chuanyong. Evolution of Interfacial Microstructure of Ni-Co Base Superalloy During Plastic Deformation Bonding and Its Bonding Mechanism[J]. 金属学报, 2022, 58(2): 129-140. [5] SHI Zengmin, LIANG Jingyu, LI Jian, WANG Maoqiu, FANG Zifan. In Situ Analysis of Plastic Deformation of Lath Martensite During Tensile Process[J]. 金属学报, 2021, 57(5): 595-604. [6] LIN Pengcheng, PANG Yuhua, SUN Qi, WANG Hangduo, LIU Dong, ZHANG Zhe. 3D-SPD Rolling Method of 45 Steel Ultrafine Grained Bar with Bulk Size[J]. 金属学报, 2021, 57(5): 605-612. [7] CAO Qingping, LV Linbo, WANG Xiaodong, JIANG Jianzhong. Magnetron Sputtering Metal Glass Film Preparation and the “Specimen Size Effect” of the Mechanical Property[J]. 金属学报, 2021, 57(4): 473-490. [8] CHEN Yongjun, BAI Yan, DONG Chuang, XIE Zhiwen, YAN Feng, WU Di. Passivation Behavior on the Surface of Stainless Steel Reinforced by Quasicrystal-Abrasive via Finite Element Simulation[J]. 金属学报, 2020, 56(6): 909-918. [9] CHEN Xiang,CHEN Wei,ZHAO Yang,LU Sheng,JIN Xiaoqing,PENG Xianghe. Assembly Performance Simulation of NiTiNb Shape Memory Alloy Pipe Joint Considering Coupling Effect of Phase Transformation and Plastic Deformation[J]. 金属学报, 2020, 56(3): 361-373. [10] WANG Lei, AN Jinlan, LIU Yang, SONG Xiu. Deformation Behavior and Strengthening-Toughening Mechanism of GH4169 Alloy with Multi-Field Coupling[J]. 金属学报, 2019, 55(9): 1185-1194. [11] Jian PENG,Yi GAO,Qiao DAI,Ying WANG,Kaishang LI. Fatigue and Cycle Plastic Behavior of 316L Austenitic Stainless Steel Under Asymmetric Load[J]. 金属学报, 2019, 55(6): 773-782. [12] Zongwei JI,Song LU,Hui YU,Qingmiao HU,Levente Vitos,Rui YANG. First-Principles Study on the Impact of Antisite Defects on the Mechanical Properties of TiAl-Based Alloys[J]. 金属学报, 2019, 55(5): 673-682. [13] Aidong TU, Chunyu TENG, Hao WANG, Dongsheng XU, Yun FU, Zhanyong REN, Rui YANG. Molecular Dynamics Simulation of the Structure and Deformation Behavior of γ/α2 Interface in TiAl Alloys[J]. 金属学报, 2019, 55(2): 291-298. [14] XIONG Jian,WEI Dean,LU Songjiang,KAN Qianhua,KANG Guozheng,ZHANG Xu. A Three-Dimensional Discrete Dislocation Dynamics Simulation on Micropillar Compression of Single Crystal Copper with Dislocation Density Gradient[J]. 金属学报, 2019, 55(11): 1477-1486. [15] Haifeng ZHANG, Haile YAN, Nan JIA, Jianfeng JIN, Xiang ZHAO. Exploring Plastic Deformation Mechanism of MultilayeredCu/Ti Composites by Using Molecular Dynamics Modeling[J]. 金属学报, 2018, 54(9): 1333-1342. No Suggested Reading articles found! Viewed Full text Abstract Cited   Shared      Discussed