本研究以雙光子微影系統針對五種雙光子材料進行材料性質分析，包含特徵尺寸、劑量累積效應、機械強度與收縮率等四種性質，再比較不同種光阻於結構成品的表現和優缺點，並建立一份光阻性能資料表。對於雙光子技術的加工製造階段來說，光阻的參數資料深具必要性，它同時也是使雙光子技術能廣泛應用不可或缺的關鍵。其中材料性質跟結構成品表現的相關性是一個值得探討的問題。然而以往文獻偏向以某種光阻或某種性質作為目標來探討，因此較缺乏不同種光阻之間性質比較的研究，也很少有為光阻製程參數做系統性的歸納、整理之研究。因此本研究鑑於這方面的文獻不足，將不同光阻性質之比較與製程參數的系統性整理作為研究目標。
本研究進行的實驗包含特徵尺寸量測、劑量累積效應量測、機械強度量測與收縮率量測。將實驗數據統整分析過後，歸納出不同光阻的性質，以及成品表現和優缺點。之後利用數據資料來建立適用光阻性能表，並以特定三維複雜結構來驗證光阻性能表之可行性。考量到使用者的方便性，最後再將光阻性能表以軟體介面的方式呈現，並且與現有的雙光子電腦輔助與製造軟體系統結合。
透過本研究之成果，預期能建立出一份雙光子製造技術之加工設計的對照參數。未來使用者在進行結構設計與製程規劃時，即可根據目標規格，對應光阻性能表快速篩選出適用光阻，省去大量前置測試的時間與心力，並能提升結構成品之成功率。

Two-photon polymerization (TPP) lithography is a powerful tool in micro-/nano-manufacturing field for its high resolution and its ability to fabricate arbitrary 3D structures. The materials, the photoresists, are important factors of good quality of structures, and many studies have been done to figure out the relationship between the photoresists and the completed structures. However, there still lacks performance comparison data among different photoresists, which is essential and served as the parameter in TPP processes. Therefore, this study focuses on five different photoresists to investigate their properties, including feature sizes, accumulation effect, mechanical strength, and shrinkage ratio, and then verifies their final performances with some specific structures. Thus, a photoresist performance table will be established and shown in the form of graphical user interface to combine with the existing TPP CAD/CAM system. Through this study, the users can quickly find manufacturing parameters of the desired structures according to the photoresist performance table. Therefore, time and cost can be saved, and the success rate of complicated structures will be improved as well.

摘要----------------------------i
Abstract-----------------------ii
致謝--------------------------iii
目錄---------------------------iv
表目錄-----------------------viii
圖目錄--------------------------x
第一章 緒論--------------------1
1.1 研究背景--------------------1
1.2 文獻回顧--------------------3
1.3 研究動機與目的--------------8
1.4 論文架構--------------------9
第二章 原理-------------------10
2.1 雙光子聚合技術-------------10
2.1.1 雙光子吸收---------------10
2.1.2 光致聚合-----------------11
2.1.3 雷射光束與體素-----------12
2.2 雙光子光阻材料-------------15
2.2.1 負光阻-------------------15
2.2.2 正光阻-------------------16
第三章 研究方法---------------17
3.1 雙光子微影系統-------------17
3.1.1 壓電式微影系統架構-------17
3.1.2 加工流程-----------------19
3.2 製程步驟及設備介紹---------21
3.2.1 光阻材料-----------------21
3.2.2 試片製備流程-------------22
3.2.3 儀器設備介紹-------------23
3.3 實驗規劃-------------------25
3.3.1 光阻性質實驗介紹---------25
3.3.2 分析與結構驗證實驗-------29
3.3.3 性能表GUI----------------31
第四章 結果與討論-------------32
4.1 光阻選用-------------------32
4.1.1 測試光阻可用性-----------32
4.1.2 光譜分析-----------------32
4.1.3 加工問題-----------------35
4.2 實驗結構設計與測試---------37
4.2.1 懸臂橋結構---------------37
4.2.2 微懸臂樑結構-------------37
4.2.3 立方體結構---------------38
4.3 特徵尺寸量測結果-----------39
4.3.1 SU8----------------------39
4.3.2 SQ50---------------------41
4.3.3 OrmoComp-----------------43
4.3.4 Mixed resin--------------45
4.3.5 PEGDA--------------------47
4.3.6 小結---------------------50
4.4 劑量累積效應量測結果-------52
4.4.1 SU8----------------------52
4.4.2 SQ50---------------------55
4.4.3 OrmoComp-----------------58
4.4.4 Mixed resin--------------61
4.4.5 PEGDA--------------------64
4.4.6 小結---------------------68
4.5 收縮率量測結果-------------70
4.5.1 SU8----------------------70
4.5.2 SQ50---------------------71
4.5.3 OrmoComp-----------------72
4.5.4 Mixed resin--------------73
4.5.5 PEGDA--------------------74
4.5.6 小結---------------------75
4.6 機械強度量測結果-----------76
4.6.1 SU8----------------------76
4.6.2 SQ-----------------------77
4.6.3 Mixed Resin--------------78
4.6.4 小結---------------------80
4.7 結構驗證實驗---------------81
4.7.1 驗證實驗結果-------------81
4.7.2 GUI介面------------------89
4.7.3 小結---------------------90
4.8 研究限制與問題討論---------91
4.8.1 量測誤差-----------------91
4.8.2 過曝問題-----------------91
第五章 結論-------------------92
5.1 結論-----------------------92
5.2 未來展望-------------------93
參考文獻-----------------------94
附錄---------------------------97

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