臺灣博碩士論文加值系統

摘要
致謝
目錄
圖目錄
表目錄
第一章 緒論
1.1研究背景
1.2閘極材料的發展
1.3高介電材料簡介
1.4研究動機
1.5文章架構
第二章 材料介紹與理論基礎
2.1 氧化鋯基本性質
2.1.1 熱穩定性
2.2 氧化鋁基本性質
2.2.1 晶體結構
2.3 介面層的產生
2.4 MOS結構理論
2.4.1 理想的MOS電容
2.4.2 金半功函數差與氧化層電荷
2.4.3金氧半電容理論計算
2.4 漏電流傳導機制
2.5.1 蕭特基發射(Schottky Emission)
2.5.2 普爾-法蘭克發射(Poole-Frenkel Emission )
2.5.3 弗勒-諾德穿隧效應(Fowler-Nordheim Tunneling)
2.5.4 歐姆傳導(Ohmic)
2.5.5 離子傳導(Ionic conduction)
2.5.6 空間電荷限制電流(SCLC)
第三章 實驗方法與步驟
3.1 實驗方法
3.1.1 氧化鋁(Al2O3)薄膜沉積
3.1.2 氧化鋯(ZrO2)薄膜沉積
3.2實驗流程
3.3 實驗設備儀器
3.4 矽基板清洗過程
3.5 電性量測
3.6 實驗參數
第四章 結果與討論
4.1 薄膜SEM分析
4.2 電容電壓特性分析
4.2.1 介電常數與氧化層電容
4.2.2有效氧化層電荷(QEFF)
4.2.3 遲滯現象
4.2.4 界面狀態密度
4.3 電流-電壓(I-V)特性曲線量測
4.4 漏電流機制分析及能障計算
4.4.1 蕭特基發射(Schottky emission)
4.4.2 F-N Tunneling
4.5 能障(∅b)計算
第五章 結論
參考文獻

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