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研究生: 羅達棋
Luo, Da-Ji
論文名稱: 低至高熵合金在拉伸行為下變形行為及微結構演化
Deformation Behavior and Microstructure Evolution of Low to High Entropy Alloys under Tensile Stress
指導教授: 蘇雲良
Soo, Yun-Liang
王俊杰
Wang, Chun-Chieh
口試委員: 黃爾文
Huang, E-Wen
翁世璋
Weng, Shih-Chang
學位類別: 碩士
Master
系所名稱: 理學院 - 物理學系
Department of Physics
論文出版年: 2019
畢業學年度: 108
語文別: 中文
論文頁數: 104
中文關鍵詞: 高熵合金同步輻射臨場X光繞射X光波形分析微結構演化
外文關鍵詞: High-entropy alloy, Synchrotron radiation, In-situ XRD, X-ray line-profile-analysis, microstructure analysis
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    • 等莫耳CoCrFeMnNi高熵合金為含有五個以上等莫耳原子比的主元素的固溶合金,其可展現出傳統單主元素合金具有更好的機械性能。本研究將以純鎳為底基,藉由添加不同數量的等莫耳主元素以形成不同熵值的合金,並就巨觀變形行為和內部微觀缺陷演化關係進行探討。本實驗使用的是國家同步輻射中心(National Synchrotron Radiation Research Center, NSRRC)的台灣光源(Taiwan Light Source, TLS) BL01B1(Nano-transmission X-ray Microscope)、BL17B2 (X-ray Scattering)、以及台灣光子源(Taiwan Photon Source, TPS) 的TPS-21A (X-ray Nanodiffraction)光束線,透過各式臨場高分辨率的X-光技術,以探討樣品在拉伸過程中合金內部微結構的演化與其變形行為間的關聯性,藉此了解多晶材料的織構特徵形成與缺陷演化。透過臨場所獲得的X-光繞射圖譜,能夠定量的估計差排密度、疊差機率、疊差能、以及雙晶機率等微結構特性參數,我們發現高熵合金與傳統合金在變形行為具有顯著的差異。由於高熵合金的嚴重晶格扭曲致使晶格能量提高,因此相較於中低熵合金有較低的疊差能。疊差能的下降,除了使得疊差在加工過程中更容易產生之外,也意味著更容易產生雙晶結構。值得一提的是,我們在實驗中發現疊差能會隨著應變量的增加而下降,此結果顛覆疊差能為定值的傳統觀念。除此之外,高熵合金織構的形成會隨著熵值越高而弱化,顯示高熵合金較一般傳統合金有較低的塑性異向性。另外本研究也使用J-PARC中心TAKUMI實驗站進行室溫臨場中子拉伸實驗,分析了不同熵值鎳基合金的彈性模數。實驗結果也證實除塑性異向性之外,高熵合金相對於中低熵合金有較低的彈性異相性。

    Equiatomic CoCrFeMnNi high-entropy alloys (HEAs) are solid solution alloys, which contain more than five principal elements with nearly equal atomic percentage, reveals extra-ordinary mechanical properties relative to traditional single principal element alloys. In this work, we compared deformation behavior and internal defect evolutions among nickel-based low-to-high entropy alloys, including the CoCrFeMnNi high-entropy alloy. The experiment performed at BL01B1 and BL17B2 beamlines of Taiwan Light Source and TPS 21A Nanodiffraction beamline of Taiwan Photon Source. In-situ high-resolution synchrotron X-ray diffraction and microscopy techniques are used to reveal texture formation and defect evolution of the alloys during tensile deformation. Quantitative evolutions of dislocation density, stacking faults probability, twinning faults probability as well as corresponding stacking fault energy can be calculated using the X-ray diffraction analysis methods. We found that high-entropy alloys are very different from the traditional low entropy alloys in the deformation behavior. The stacking fault energy of high-entropy alloy is significantly lower than that of medium and low entropy alloys due to its severe lattice distortion. Therefore, stacking faults and twins can be produced easily in high-entropy alloys. We also found that the stacking fault energy decreases with the increase of strain, which is different from the traditional concept of fixed stacking fault energy during deformation. In addition, the texture formation is obvious as the increase of alloy entropy, which implies that high-entropy alloys exhibit lower plastic anisotropy than traditional alloys. Besides, elastic moduli of nickel-based alloys with different entropies were analyzed by using in-situ room temperature tensile neutron experiments carried out at TAKUMI beamline of Japan Proton Accelerator Research Complex facility. The experimental results also suggest that elastic anisotropy of high-entropy alloys is less obvious than medium- and low-entropy alloys.

    摘要 II Abstract III 誌謝 IV 目錄 V 圖目錄 VIII 表目錄 XIII 第1章、 緒論 1 1-1前言 1 第2章、 理論基礎與文獻回顧 2 2-1高熵合金四大效應 2 2-2高熵合金的機械性質 5 2-4 微結構演化對機械性質影響 7 2-5 疊差能 13 第3章、 實驗方法與步驟 19 3-1高熵合金樣品的製備流程 19 3-1-1真空電弧熔煉 20 3-1-2 均質化處理 20 3-1-3 滾軋 21 3-1-4 退火 21 3-1-5 拉伸試片表面研磨 21 3-1-6 高熵合金的微結構 22 3-2 X光繞射與中子散射 23 3-2-1 同步輻射X光繞射(X-ray diffraction, XRD) 23 3-2-2 X光奈米繞射(X-ray Nanodiffraction, XND) 28 3-3 繞射數據分析 29 3-3-1 GSAS-|| 29 3-3-2 XMAS 31 3-3-3 CMWP(Convolutional Multiple Whole Profile fitting) 32 3-4 自製微型拉伸機 35 3-4-1元件 35 3-4-2元件介紹 36 3-4-3理論拉伸計算 38 3-4-4 硬體接線 40 3-4-5軟體撰寫 42 3-4-5機構設計 44 第4章、 結果與討論 47 4-1不同熵值合金巨觀機械性質 47 4-2 不同熵值合金織構形成特性 57 4-2-1 In-situ拉伸下晶面變化 57 4-3 不同熵值合金微結構演化特性 78 4-4 疊差能 85 4-5 比較高至低熵合金其微結構演化 96 第5章、 總結與未來展望 100 5-1 總結 100 5-2 未來展望 100 參考文獻 101

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