新式相場模擬法應用於鐵電材料微晶域之研究

Ming-Hsien Shen; 沈明憲

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/42273

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	舒貽忠(Yi-Chung Shu)
dc.contributor.author	Ming-Hsien Shen	en
dc.contributor.author	沈明憲	zh_TW
dc.date.accessioned	2021-06-15T00:56:50Z	-
dc.date.available	2010-08-08
dc.date.copyright	2008-08-08
dc.date.issued	2008
dc.date.submitted	2008-08-04
dc.identifier.citation	[1] Y. C. Shu, J. H. Yen, and H. Z. Chen Chen A Novel Field Simulation of Microstructure in Ferroelectrics. 2007. [2] Y. C. Shu, J. H. Yen, and H. Z. Chen Constrained Modeling of Domain Patterns in Rhombohedral Ferroelectrics. 2008. [3] Y. C. Shu*, J. H. Yen Multivariant Model of Martensitic Microstructure in Thin Films. 2007. [4] J. H. Yen Applied of Multrirank Lamination Theory to the Modeling of Ferroelectric and Martensitic Materials. 2008 [5] J. H. Yen Material Parameters of Single Domain Ferroelectric Single Crystals in the Rhomohedral Phase. 2008 [6] 陳宏志平行架構與快速演算法應用於麻田散鐵與磁性材料微結構之研究, 2007 [7] 徐建輝新式相場法應用於麻田散鐵微結構之研究, 2007 [8] R.E. Newnham and G.R. Ruschau. Smart Electroceramics. J. Am. Ceram. Soc. J. Am. Ceram. Soc., 74:463-480, 1991. [9] G. S. Agnes and D. J. Inman. Nonlinear Piezoelectric Vibration Absorbers. Smart Materials and Structures, 5:704-714, 1996. [10] H. T. Banks, D. J. Inman, and D. J. Leo. An Experimentally Validated Damage Detection Theory in Smart Structure. Journal of Sound and Vibration, 191:859-880, 1996. [11] M. I. Friswell, D.J. Inman, and R. W. Rietz. Active Damping of Thermally Induced Vibrations. Journal of Intelligent Material Systems and Structures, 8:678-685, 1997. [12] J. W. Cahn. (1961) On Spinodal Decomposition. Acta Metallurgica, 9:795-801, 1961. [13] J. W. Cahn and J. E. Hilliard (1958) Free Energy of a Nonuniform System. I. Interfacial Free Energy. J. Chem. Phys., 28:258-267, 1958. [14] S. M. Allen and J. W. Cahn. A Microscopic Theory of Domain Wall Motion and its Experimental Verification in Fe-Al Alloy DomainGrowth Kinetics. Journal de Physique. C7:C7-51, 1997. [15] J. A. Hooton and W. J. Merz. Etch Patterns and Ferroelctric Domains in BaTiO3 Single Crystal. Physical Review, 98:409-413, 1995. [16] W. R. Cook. Domain Twinning in Barium Titanate Ceramics. Journal of the American Ceramic Society, 39:17-19, 1956. [17] F. Kulcasar. A Microstructure Study of Barium Tinate Ceramics. Journal of the American Ceramic Society, 39:13-17, 1956. [18] E. A. Little. Dynamical Behavior of Domains Walls inBarium Titanate. Physical Review, 98:978-984, 1995. [19] ShinMC, ChungSJ, LeeSG, FeigelsonRS Growth and observation of domain structure of PZN-PT single crystal. 2003. [20] 葉潔樺鐵電晶體在力電耦合下之遲滯表現與電域旋轉:實驗與模擬, 2007 [21] G. Arlt. Twinning in the Ferroelectric and Ferroelastic Ceramics: Stress Relief. Journal of Materials Science, 25:2655-2666, 1990. [22] D. Iannece, A Romano, and E. S. Suhubi. A Thermodynamical Approach to the Structure of Weiss Domains in Deformable Ferroelctric Crystals. Interactions Journal of Engineering Science, 32:1941-1950, 1994. [23] G. Arlt and P. Sasko. Domain Configuration and Equilibrium Size of Domain in BaTiO3 Ceramics. Journal of Applied Physics, 51:4956-4960, 1980. [24] J. Ricote, R. W. Whatmore, and D. J. Barber. Studies of the Ferroelctric DomainConfiguration and Polarization of Rhombohedral PZT Ceramics. Journal of Physics:Condensed Matter, 12:323-337, 2000. [25] S. Wada, S. Suzuki, T. Noma, T. Suzuki, M. Osada, M. Kakihana, S. E. Park, L. E. Cross, and T. R. Shrout. Enhanced Piezoelectric Property of Barium Titnate Single Crystals with Engineered Domain Configurations. Japanese Journal of Applied Physics, 38:5505-5511, 1999. [26] 羅克玲先進記憶體技術向埃米級設計發展, 2005. [27] M. J. Haun, E. Furman, S. J. Jang, H. A. McKinstry, and L. E. Cross. Thermodynamic Theory of PbTiO3. Journal of Applied Physics, 62:3331-3338, 1987. [28] H. L. Hu and L. Q. Chen. Computer Simulation of 90 degrees Ferroelectric Domain Formation in Two Dimensions. Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing, 238:182-191, 1997. [29] H. L. Hu and L. Q. Chen. Three-dimensional Computer Simulation of Ferroelectric Domain Formation. Journal of the American Ceramic Society, 81:492-500, 1998. [30] J. Wang, S. Q. Chen, and T.Y. Zhang. The Effect of Mechanical Strains on the Ferroelectric and Dielectric Properties of a Model Single Crystal-Phase Field Simulation. Acta Materialia, 53:2495-2507, 2005. [31] J. Wang, S.Q. Shi, L. Q. Chen , T. Y. Zhang. Phase Field Simulations of Ferroelectric/Ferroelectric Polarization Switching. Acta Materialia, 52:749-764, 2004. [32] J. Wang, Y. Li, L. Q. Chen, and T. Y. Zhang. The Effect of Mechanical strains on the Ferroelectric and Dielectric Properties of a Model Single Crystal-Phase Field Simulation. Acta Materialia, 53:2495-2507, 2005. [33] W. Zhang and K. Bhattacharya. A Computional Model of Ferroelectric Domains. Part1 Model Formulation and Domain Switching. Acta Materialia, 55:185-198, 2005. [34] W. Zhang and K. Bhattacharya. A Computional Model of Ferroelectric Domains. Part2 Grain Boundaries and Defect Pinning. Acta Materialia, 53:2495-2507, 2005. [35] K. Dayal and K. Bhattacharya. Areal-Space Non-Local Phase-Field Model of Ferroelectric Domain Patterns in Complex Geometries. Acta Materialia, 55:199-209, 2005. [36] A. J. Bell Phenomenologically Derived Electric Field-Temperature Phase Diagrams and Piezoelectric Coefficients for Single Crystal Barium Titanate under Fields along Different Axes. Journal of Applied Physics, 89:3907-3914, 2001. [37] Z. Suo and W. Lu. Composition Modulation and Nanophase Separation in Binary Epilayer. Journal of the Mechanics and Physics of Solids, 48:211-232, 2000. [38] J. Y. Li and Liu. On Ferroelectric Crystals with Engineered Domain Configurations. Journal of the Mechanics and Physics of Solids, 52:1719-1742, 2004. [39] Derek Vraik. Magnetism Principles and applications, 1997 [40] 呂正傑、詹世雄鐵電記憶體簡介, 2003
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/42273	-
dc.description.abstract	鐵電材料具有優越介電性、鐵電性、壓電性及焦電性，近年來應用於記憶體元件、電感元件、壓電致動器與光調元件等等。而這些性質源自於材料內部秩序性的微結構排列與演化所導致的宏觀反應。因此，瞭解微觀結構的演化，是必要的工作。本文中發展出一套能夠描述鐵電材料微晶域演化的新式相場模型並且進行數值模擬分析。在傳統相場法中，因為以極化向量做為次序參數，而材料內能之數學表達式則藉由特殊藍道多項式展開次序參數得之，其結果相當繁瑣，並需要大量可調參數。而新式相場法利用這組新的場變數，系統的能量基態結構便可以用解析的數學式描寫，且其數學形式可適用於所有的晶體對稱性。穩態的鐵電材料微結構乃決定於系統總能量之最低點，使得整體微結構需滿足應變與極化的諧和條件，而鐵電材料晶域便是於這樣的規範下排列而成。在本文研究針對鈦酸鋇之正方晶與菱形晶兩種晶體結構進行模擬，其結果發現晶域間始終滿足諧和條件，也與實驗結果符合。最後，我們施加電場，以觀察鐵電材料的壓電性與遲滯性現象。	zh_TW
dc.description.abstract	Ferroelectric materials exhibit spontaneous polarization and distortion under the transformation temperature, giving rise to very characteristic microstructures. The arrangement and evolution of microstructures can induce significant nonlinear behaviors, so they are widely used as smart materials. As ferroelectric microstructures are the key to achieving the exceptional properties, it is essential to investigate the mechanism that governs their formation and evolution. In this thesis, we study the prescribed issue by developing a non-conventional phase-field model. It is based on energy arguments where competing energetics are used to describe the coarsening, refinement, selection, and alignment of ferroelectric domains. In addition to the conventional use of polarization as order parameters, we adopt a new set of field variables motivated by multirank laminates to characterize energy-minimizing domain configurations. As a result, the energy-well structure can be expressed explicitly in a unified fashion, and the number of input parameters in the present framework is reduced. This model is applied to domain simulation in both the tetragonal and rhombohedral ferroelectrics. Several electromechanical self-accommodation patterns are obtained in the simulations and found in good agreement with experimental observations. Besides, rearrangements of domains under applied electric field along polar/non-polar directions are investigated. Preliminary result of hysteretic behavior is also presented. Finally, parameter study is also conducted to verify the model.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T00:56:50Z (GMT). No. of bitstreams: 1 ntu-97-R95543055-1.pdf: 43452196 bytes, checksum: ca90ef4e26fb40bb032a9bdb50ed7127 (MD5) Previous issue date: 2008	en
dc.description.tableofcontents	目錄第1章導論 1 1-1 背景與研究動機 1 1-2 鐵電材料介紹 1 1-3 相場法介紹 3 1-4 本文架構 5 第2 章理論架構 6 2-1 數學模型 6 2-1-1 鐵電兄弟晶 6 2-1-2 鐵電晶體能量 9 2-2 熱力學驅動力與演化方程式 12 2-3限制型態數學模型 15 2-4 傅立葉轉換解力學平衡問題 17 2-5 傅立葉轉換解電場問題 22 第3 章數值計算 25 3-1 無因次化 25 3-2 時間積分計算 27 3-3 各項自由能之離散型式 31 3-4 計算流程 34 第4 章數值計算 39 4-1 鈦酸鋇(BaTiO3)材料 39 4-2 模擬正方晶微結搆 39 4-2-1 限制型態數學模型 42 4-2-2 完全型態數學模型 48 4-2-3 微小項探討 54 4-3 模擬菱形晶微結搆 56 4-3-1 限制型態數學模型 58 4-3-2 完全型態數學模型 63 4-3-3 模擬結果與實際觀察比較 67 4-4 材料自主性調適(self-accommodation)探討 68 4-5 晶壁探討 71 4-5-1 斷面分析 71 4-5-2介面能係數對微結構影響之探討 73 4-6 異向能係數對微結構影響之探討 76 4-7 極化-電場曲線圖 80 4-7-1 外加[100]方向電場探討 80 4-7-2外加[1 ̅10] 方向電場探討 86 4-7-3遲滯特性探討 89 第5 章結論與未來展望 91 5-1 結論 91 5-2 未來展望 92 參考文獻 94 參考文獻 98 附錄A 以格林函數計算應力與自發性應變的關係 98 附錄B 快速傅立葉轉換應用於有限域與無限域褶積問題 101
dc.language.iso	zh-TW
dc.subject	微結構成形	zh_TW
dc.subject	多階層狀結構	zh_TW
dc.subject	鐵電材料	zh_TW
dc.subject	相場法模型	zh_TW
dc.subject	Multirank lamination	en
dc.subject	Pattern formation	en
dc.subject	Phase-field models	en
dc.subject	Ferroelectric single crystal	en
dc.title	新式相場模擬法應用於鐵電材料微晶域之研究	zh_TW
dc.title	A Novel Phase Field Simulation of Ferroelectric Micro-Domain	en
dc.type	Thesis
dc.date.schoolyear	96-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳國慶(Kuo-Ching, Chen),謝宗霖(Tzong-Lin Jay, Shieh)
dc.subject.keyword	鐵電材料,相場法模型,微結構成形,多階層狀結構,	zh_TW
dc.subject.keyword	Ferroelectric single crystal,Phase-field models,Pattern formation,Multirank lamination,	en
dc.relation.page	97
dc.rights.note	有償授權
dc.date.accepted	2008-08-04
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	應用力學研究所	zh_TW
顯示於系所單位：	應用力學研究所

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