热电材料断裂力学的若干进展
Some Advances in Fracture Mechanics of Thermoelectric Material
DOI: 10.12677/IJM.2018.72007, PDF,    国家自然科学基金支持
作者: 刘庆楠, 丁生虎*:宁夏大学,数学统计学院,宁夏 银川
关键词: 热电材料裂纹断裂力学数值计算Thermoelectric Materials Crack Fracture Mechanics Numeral Calculation
摘要: 热电材料是一种将热能和电能进行转换的功能材料。由于热电材料的本构方程是非线性的,相应的力学分析具有很大的挑战性,因此对热电材料在断裂力学中的研究进展进行梳理具有十分重要的意义。本文介绍了热电材料的发展现状和应用前景,综述了热电材料断裂力学的最新研究进展,包括热电材料断裂力学问题的理论研究、数值研究和热电材料断裂力学中的实验研究。最后对未来热电材料的断裂力学研究进行了展望。
Abstract: Thermoelectric material is a kind of functional material which converts heat energy and electric energy to each other. Since the constitutive equations of thermoelectric materials are nonlinear and the corresponding mechanical analysis is very challenging, it is of great significance to sort out the research progress of thermoelectric materials in fracture mechanics. In this paper, the development status and application prospect of thermoelectric materials are introduced. The latest research progress of fracture mechanics of thermoelectric materials is reviewed, including the theoretical research and numerical study of thermoelectric materials fracture mechanics, and experimental research in fracture mechanics of thermoelectric materials. Finally, the future research on the fracture mechanics of thermoelectric materials is prospected.
文章引用:刘庆楠, 丁生虎. 热电材料断裂力学的若干进展[J]. 力学研究, 2018, 7(2): 54-65. https://doi.org/10.12677/IJM.2018.72007

参考文献

[1] 王超, 张蕊, 杜欣, 等. 新型热电材料综述[J]. 电子科技大学学报, 2017, 46(1): 133-150.
[2] 范天佑. 断裂理论基础[M]. 北京: 科学出版社, 2003.
[3] Wu, H.J., Chen, B.Y. and Cheng, H.Y. (2017) The p-n, Conduction Type Transition in Ge-Incorporated Bi 2 Te 3, Thermoelectric Materials. Acta Materialia, 122, 120-129. [Google Scholar] [CrossRef
[4] 徐桂英, 葛昌纯. 热电材料的研究和发展方向[J]. 材料导报, 2000, 14(11): 38-41.
[5] 马秋花, 赵昆渝, 李智东, 等. 热电材料综述[J]. 电工材料, 2004(1): 43-47.
[6] 缪婷婷, 马维刚, 李震, 等. 一种测量热电材料塞贝克系数的新方法[J]. 工程热物理学报, 2011, 32(4): 629-633.
[7] Jaumot, F.E. (1958) Thermoelectric Effects. Proceedings of the IRE, 46, 538-554. [Google Scholar] [CrossRef
[8] 任尚芬, 程伟. 能源效率、热电效应和纳米技术[J]. 物理, 2007, 36(9): 673-675.
[9] Hicks, L.D., Harman, T.C. and Dresselhaus, M.S. (1993) Use of Quantum-Well Superlattices to Obtain a High Figure of Merit from Nonconventional Thermoelectric Materials. Applied Physics Letters, 63, 3230-3232. [Google Scholar] [CrossRef
[10] Jin, Z.H. and Wallace, T.T. (2014) Functionally Graded Thermoelectric Materials with Arbitrary Property Gradations: A One-Dimensional Semianalytical Study. Journal of Electronic Materials, 44, 1-6.
[11] Fengrong, Y.U., Chen, S., Liu, W., et al. (2012) Current Studies and Perspective of Bi_2Te_3 Thermoelectric Materials. Journal of Yanshan University, 32, 525-540.
[12] Li, S., Li, X., Ren, Z.F., et al. (2018) Recent Progress on High Performance of Tin Chalcogenides Thermoelectric Materials. Journal of Materials Chemistry A, 6, 2432-2448. [Google Scholar] [CrossRef
[13] Zhang, A.B., Wang, B.L., Wang, J., et al. (2017) Effect of Cracking on the Thermoelectric Conversion Efficiency of Thermoelectric Materials. Journal of Applied Physics, 121, Article ID: 045105. [Google Scholar] [CrossRef
[14] Today, P. (2007) New High-Efficiency Thermoelectric Material Achieved by Cracking the Crystal. Journal of AIP, 336-338, 842-845.
[15] Wang, Y.Z. (2015) Effective Material Properties of Thermoelectric Composites with Elliptical Fibers. Applied Physics A, 119, 1081-1085. [Google Scholar] [CrossRef
[16] 宿太超. 高性能热电材料的高温高压合成研究[D]: [博士学位论文]. 长春: 吉林大学, 2009.
[17] 程靳, 赵树山. 断裂力学[M]. 北京: 科学出版社, 2006.
[18] 康颖安. 断裂力学的发展与研究现状[J]. 湖南工程学院学报: 自然科学版, 2014, 16(24): 39-42.
[19] Song, H.P. and Li, C.F.G.J. (2015) Two-Dimensional Problem of a Crack in Thermoelectric Materials. Journal of Thermal Stresses, 38, 325-337. [Google Scholar] [CrossRef
[20] Zhang, A.B. and Wang, B.L. (2013) Crack Tip Field in Thermoelectric Media. Theoretical & Applied Fracture Mechanics, 66, 33-36. [Google Scholar] [CrossRef
[21] Zhang, A.B. and Wang, B.L. (2016) Explicit Solutions of an Elliptic Hole or a Crack Problem in Thermoelectric Materials. Engineering Fracture Mechanics, 151, 11-21. [Google Scholar] [CrossRef
[22] Zhang, A.B., Wang, B.L., Wang, J., et al. (2017) Thermodynamics Analysis of Thermoelectric Materials: Influence of Cracking on Efficiency of Thermoelectric Conversion. Applied Thermal Engineering, 127, 1442-1450. [Google Scholar] [CrossRef
[23] Zeleke, M.A., Xin, L. and Liu, L.S. (2017) Bond Based Peridynamic Formulation for Thermoelectric Materials. Materials Science Forum, 51-59. [Google Scholar] [CrossRef
[24] Wang, P. and Wang, B.L. (2017) Thermoelectric Fields and Associated Thermal Stresses for an Inclined Elliptic Hole in Thermoelectric Materials. International Journal of Engineering Science, 119, 93-108. [Google Scholar] [CrossRef
[25] Lee, E.P., Hsia, S.H., Lin, J.J., et al. (2017) Hemodynamic Analysis of Pediatric Septic Shock and Cardiogenic Shock Using Transpulmonary Thermodilution. Biomed Research International, 2017, Article ID: 3613475. [Google Scholar] [CrossRef] [PubMed]
[26] Jin, Z.H. (2015) Thermal Stresses in a Multilayered Thin Film Thermoelectric Structure. Microelectronics Reliability, 54, 1363-1368.
[27] Jin, Z.H., Wallace, T.T., Lad, R.J., et al. (2014) Energy Conversion Efficiency of an Exponentially Graded Thermoelectric Material. Journal of Electronic Materials, 43, 308-313. [Google Scholar] [CrossRef
[28] Liu, Y., Wang, B.L. and Zhang, C. (2016) Thermoelastic Behavior of a Thermoelectric Thin-Film Attached to an Infinite Elastic Substrate. Philosophical Magazine, 97, 43-57.
[29] 郭亚博. 热电材料热冲击阻力性能的研究[D]: [硕士学位论文]. 哈尔滨: 哈尔滨工业大学, 2015.
[30] Wang, B.L., Guo, Y.B. and Zhang, C.W. (2016) Cracking and Thermal Shock Resistance of a Bi2Te3, Based Thermoelectric Material. Engineering Fracture Mechanics, 152, 1-9. [Google Scholar] [CrossRef
[31] Huang, M.J., Chou, P.K. and Lin, M.C. (2006) Thermal and Thermal Stress Analysis of a Thin-Film Thermoelectric Cooler under the Influence of the Thomson Effect. Sensors and Actuators A: Physical, 126, 122-128. [Google Scholar] [CrossRef
[32] Hikage, Y., Masutani, S., Sato, T., et al. (2007) Thermal Expansion Properties of Thermoelectric Generating Device Component. 26th International Conference on Thermoelectrics Proceedings, Jeju, 3-6 June 2007, 331-335. [Google Scholar] [CrossRef
[33] Ravi, V., Firdosy, S., Caillat, T., et al. (2009) Thermal Expansion Studies of Selected High-Temperature Thermoelectric Materials. Journal of Electron Materials, 38, 1433-1442. [Google Scholar] [CrossRef
[34] Chuan-Bin, Y.U. and Gao, C.F. (2016) Analysis of a Circular Arc-Crack in Thermoelectric Media. 207-212.
[35] Song, H.P. and Song, K. (2016) Electric and Heat Conductions across a Crack in a Thermoelectric Material. Journal of Theoretical & Applied Mechanics, 46, 83-98. [Google Scholar] [CrossRef
[36] Zhang, A.B. and Wang, B.L. (2013) Applicability of the Crack Faces Thermoelectric Boundary Conditions for Thermopiezoelectric Materials. Mechanics Research Communications, 52, 19-24. [Google Scholar] [CrossRef
[37] Zang, A.B. and Wang, B.L. (2016) Temperature and Electric Potential Fields of an Interface Crack in a Layered Thermoelectric or Metal/Thermoelectric Material. International Journal of Thermal Sciences, 104, 396-403. [Google Scholar] [CrossRef
[38] Ding, S.H., Zhou, Y.T. and Li, X. (2014) Interface Crack Problem in Layered Orthotropic Materials under Thermo-Mechanical Loading. International Journal of Solids & Structures, 51, 4221-4229. [Google Scholar] [CrossRef
[39] Ding, S.H. and Li, X. (2015) Thermoelastic Analysis of Nonhomogeneous Structural Materials with an Interface Crack under Uniform Heat Flow. Elsevier Science Inc., New York.
[40] Perez-Aparicio, J.L., Taylor, R.L. and Gavela, D. (2007) Finite Element Analysis of Nonlinear Fully Coupled Thermoelectric Materials. Computational Mechanics, 40, 35-45. [Google Scholar] [CrossRef
[41] Clin, T., Turenne, S., Vasilevskiy, D., et al. (2009) Numerical Simulation of the Thermomechanical Behavior of Extruded Bismuth Telluride Alloy Module. Journal of Electronic Materials, 38, 994-1001. [Google Scholar] [CrossRef
[42] Turenne, S., Clin, T.H., Vasilevskiy, D., et al. (2010) Finite Element Thermomechanicial Modeling of Large Area Thermoelectric Generators Based on Bismuth Telluride Alloys. Journal of Electronic Materials, 39, 1926-1933. [Google Scholar] [CrossRef
[43] Picard, M., Turenne, S. and Masut, R.A. (2013) Numerical Simulation of Performance and Thermomechanical Behavior of Thermoelectric Modules with Segmented Bismuth-Telluride-Based Legs. Journal of Electronic Materials, 42, 2343-2349. [Google Scholar] [CrossRef
[44] 杨利娜. 单边裂纹电磁热止裂强化对比研究及裂纹扩展实验方法[D]: [硕士学位论文]. 秦皇岛: 燕山大学, 2013.
[45] Chen, L.S. and Lee, J.Y. (2015) Effect of Pulsed Heat Power on the Thermal and Electrical Performances of a Thermoelectric Generator. Applied Energy, 150, 138-149. [Google Scholar] [CrossRef
[46] Wang, B.L. (2017) A Finite Element Computational Scheme for Transient and Nonlinear Coupling Thermoelectric Fields and the Associated Thermal Stresses in Thermoelectric Materials. Applied Thermal Engineering, 110, 136-143. [Google Scholar] [CrossRef
[47] Li, J.F., Pan, Y., Wu, C.F., et al. (2017) Processing of Advanced Thermoelectric Materials. Scientia Sinica Technologica, No. 9, 1-18.
[48] Suhir, E. (2013) Could Electronics Reliability Be Predicted, Quantified and Assured. Microelectronics Reliability, 53, 925-936. [Google Scholar] [CrossRef
[49] Ni, J.E. and Case, E.D. (2013) Thermal Fatigue of Cast and Hot-Pressed Lead-Antimony-Silver-Tellurium (LAST) Thermoelectric Materials. Journal of Electronic Materials, 42, 1382-1388. [Google Scholar] [CrossRef
[50] Fukada, Y. (2010) Thermoelectric Element and Thermoelectric Module. US 20100059096 A1.
[51] Pierce, J. and Vaudo, R.P. (2010) Methods of Depositing Epitaxial Thermoelectric Films Having Reduced Crack and/or Surface Defect Densities and Related Devices. WO, US 7804019 B2.
[52] Jayaram, V., Shivakumara, C., Satyanarayana, M., et al. (2012) Study of the Stability of Na0.7CoO2 Thermoelectric Materials under Shock Dynamic Loading in a Shock Tube.
[53] Wang, P., Barcohen, A., Yang, B., et al. (2006) Analytical Modeling of Silicon Thermoelectric Microcooler. Journal of Applied Physics, 100, Article ID: 014501. [Google Scholar] [CrossRef
[54] 乐群. 高压烧结热电材料残余应力分析与数值模拟[D]: [硕士学位论文]. 武汉: 武汉理工大学, 2008.
[55] 戚德奎, 鄢永高, 李涵, 等. 快速急冷法对β-Zn4+xSb3材料热电及力学性能的影响[J]. 无机材料学报, 2010, 25(6): 603-609.
[56] Case, E.D. (2006) Weibull Analysis of the Biaxial Fracture Strength of a Cast p-Type LAST-T Thermoelectric Material. Philosophical Magazine Letters, 86, 673-682. [Google Scholar] [CrossRef
[57] Yoneda, S., Ohno, Y., Isoda, Y., et al. (2009) Mechanical Properties of PbTe Thermoelectric Materials by Three-Point Bending Fracture Strength Test. Journal of the Society of Materials Science Japan, 46, 174-177.
[58] Gao, P., Berkun, I., Schmidt, R.D., et al. (2014) Transport and Mechanical Properties of High-ZT, Mg2.08Si0.4−x, Sn0.6Sbx, Thermoelectric Materials. Journal of Electronic Materials, 43, 1790-1803. [Google Scholar] [CrossRef
[59] Ni, J.E., Case, E.D., Schmidt, R.D., et al. (2013) The Thermal Expansion Coefficient as a Key Design Parameter for Thermoelectric Materials and Its Relationship to Processing-Dependent Bloating. Journal of Materials Science, 48, 6233-6244. [Google Scholar] [CrossRef
[60] Schmidt, R.D., Case, E.D., Iii, J.G., et al. (2012) Room-Temperature Mechanical Properties and Slow Crack Growth Behavior of Mg2Si Thermoelectric Materials. Journal of Electronic Materials, 41, 1210-1216. [Google Scholar] [CrossRef
[61] 刘刚. Bi2Te3或CoSb3宽温域热电材料的制备界面结构和力学性能[D]: [硕士学位论文]. 武汉: 武汉理工大学, 2012: 1-15.
[62] Eilertsen, J., Subramanian, M.A. and Kruzic, J.J. (2013) Fracture Toughness of Co4Sb12 and In0.1Co4Sb12 Thermoelectric Skutterudites Evaluated by Three Methods. Journal of Alloys and Compounds, 552, 492-498. [Google Scholar] [CrossRef
[63] Ma, J.M., Firdosy, S.A., Kaner, R.B., et al. (2014) Hardness and Fracture Toughness of Thermoelectric La3−xTe4. Journal of Materials Science, 49, 1150-1156. [Google Scholar] [CrossRef
[64] Fan, X. (2013) Mechanical Characterization of Hydroxyapatite, Thermoelectric Materials and Doped Ceria.
[65] Tyagi, K., Gahtori, B., Bathula, S., et al. (2015) Crystal Structure and Mechanical Properties of Spark Plasma Sintered Cu2Se: An Efficient Photovoltaic and Thermoelectric Material. Solid State Communications, 207, 21-25. [Google Scholar] [CrossRef

为你推荐