氧化鋅是一種擁有廣泛用途和低成本的 II-VI族材料，奈米結構擁有耐高溫、型態可控性，低功函數且易於製備。研究主要方向分為兩部分，首先第一部分使用氧化鋅靶材在RF磁控濺射系統在康寧玻璃基板上沉積約100 nm之晶種層，之後將沉積完成的氧化鋅晶種薄膜基板以水熱法製作，使用硝酸鋅 (Zinc nitrate, Zn(NO₃)₂)、六亞甲基四胺 (HMT)混合，在90℃的環境中生長6小時，第二部分在將鉑奈米粒子吸附於生長完成的試片表面後再進行400℃退火，完成氧化鋅奈米柱感測器，後續進行各種特性分析及電化學測量測定，利用鉑奈米粒子吸附氧化鋅感測器表面來提升量測電流特性。
延伸式閘極場效電晶體(EGFET)的感測端使用的是製備完成氧化鋅奈米柱感測器，探討不同酸鹼值的電壓電流變化。研究發現鉑奈米顆粒修飾氧化鋅奈米電流靈敏度由15.50 µA/pH，提升至47.82 µA/pH，電壓靈敏度由28.95 mV/pH提升至49.83mV/pH，主要推測是表面吸附鉑奈米粒子會使材料導電率提升，奈米柱表面密度及表面活性位點也會增加，使能階不受費米釘扎效應影響，以提升氧化鋅奈米柱反應靈敏度。

Zinc oxide is a II-VI material with a wide range of uses and low cost. The nanostructure has high temperature resistance, shape controllability, low work function and easy preparation. The main research direction is divided into two parts. First, the first part uses a zinc oxide target to deposit a seed layer of about 100 nm on the Corning glass substrate using the RF magnetron sputtering system, and then the deposited zinc oxide seed film substrate is treated with water Manufactured by thermal method, using a mixture of zinc nitrate (Zn(NO₃)₂) and hexamethylenetetramine (HMT), grown in an environment of 90℃ for 6 hours, the second part is the adsorption of platinum nanoparticles on The surface of the grown test piece is then annealed at 400°C to complete the zinc oxide nanorods sensor. Various characteristic analysis and electrochemical measurements are performed subsequently. The platinum nano-particles are adsorbed on the surface of the zinc oxide sensor to increase the amount. Measure current characteristics.
The sensing end of the extended gate field effect transistor (EGFET) uses a prepared zinc oxide nanocolumn sensor to investigate the voltage and current changes of different pH values. The study found that the current sensitivity of zinc oxide nanoparticles modified by platinum nanoparticles increased from 15.50 µA/pH to 47.82 µA/pH, and the voltage sensitivity increased from 28.95 mV/pH to 49.83 mV/pH. It is mainly speculated that the surface adsorption of platinum nanoparticles would To increase the conductivity of the material, the surface density of nanopillars and surface active sites will also increase, so that the energy level is not affected by the Fermi pinning effect, so as to improve the sensitivity of the zinc oxide nanorods.

摘要...i
Abstract...ii
誌謝...iii
目錄...iv
表目錄...vi
圖目錄...vii
第一章 緒論...1
1.1前言...1
第二章 文獻回顧...3
2.1氧化鋅奈米材料簡介...3
2.1.1原子晶格結構介紹...3
2.1.2奈米結構...4
2.1.3光學性質...5
2.2薄膜製作流程...6
2.3氧化鋅奈米結構合成方式介紹...8
2.3.1物理氣相沉積法(PVD)...8
2.3.2化學氣相沉積法(CVD)...10
2.3.3溶膠-凝膠法(Sol–Gel Process)...11
2.3.4水溶液法 (Aqueous solution method)...12
2.3.5水熱法 (Hydrothermal method)...14
2.4 延伸式閘極場效電晶體之演進...16
2.5 酸鹼值理論...18
2.5.1酸鹼值電化學測量原理...18
2.5.2延伸式閘極場效應電晶體...20
2.5.3表面吸附鍵結模型...21
2.5.4電雙層(Electric Double layer)模型...23
2.5.5費米能階釘扎效應(Fermi Level Pinning)...26
第三章 實驗步驟與量測設備分析...28
3.1實驗室化學藥品與貴重儀器...28
3.1.1實驗化學藥品介紹...28
3.1.2使用儀器...29
3.2儀器分析原理與介紹...30
3.2.1射頻磁控濺鍍系統 (RF magnetic sputtering system)...30
3.2.2場發射掃描式電子顯微鏡(Field Emission Scanning Electron Microscopy, FE-SEM)...32
3.2.3能量色散X射線譜(Energy-Dispersive-X-ray Spectroscopy ,EDS)...33
3.2.4 X射線繞射儀(X-ray diffraction, XRD)...34
3.2.5光致發光(Photoluminescence, PL)...35
3.2.6穿透式電子顯微鏡(Transmission electron microscopy, TEM)...36
3.2.7 X-射線光電子能譜儀（X-ray photoelectron spectroscopy, XPS）...37
3.3實驗步驟...38
3.3.1基板清洗...39
3.3.2氧化鋅晶種層製程...40
3.3.3吸附鉑奈米粒子及氧化鋅奈米柱生長...41
3.3.4氧化鋅奈米柱及鉑奈米粒子修飾氧化鋅奈米柱材料特徵分析...43
3.3.5氧化鋅奈米柱及吸附鉑奈米粒子氧化鋅奈米柱酸鹼值電性特性分析...43
第四章 結果與討論...44
4.1氧化鋅奈米柱材料特徵分析...44
4.1.1氧化鋅奈米柱場發射電子顯微鏡分析(FE-SEM)...44
4.1.2金屬觸媒吸附氧化鋅奈米柱場發射電子顯微鏡分析...46
4.1.3金屬觸媒吸附於氧化鋅奈米柱之穿透式掃描式電子顯微鏡...47
4.1.4 X-ray繞射儀之氧化鋅奈米柱分析...50
4.1.5光致發光之氧化鋅奈米柱分析...52
4.1.6 X-射線光電子能譜儀之鉑奈米粒子修飾氧化鋅奈米柱分析...53
4.2氧化鋅奈米柱酸鹼值感測器電性分析...56
4.2.1氧化鋅酸鹼值感測器測量...56
4.2.2氧化鋅奈米柱之延伸式閘極場效電晶體之元件特性...57
4.2.3鉑奈米粒子修飾氧化鋅奈米柱之延伸式閘極場效電晶體之元件特性...60
4.2.4酸鹼值穩定性比較...63
4.2.5酸鹼值遲滯現象比較...65
第五章 結論...67
5.1結論...67
5.2未來展望...67
參考文獻 ...68
Exctended Abstract...73

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