臺灣博碩士論文加值系統

目錄
誌謝 I
摘要 II
目錄 VII
圖目錄 XI
第一章 介紹 1
1-1 奈米銀線之合成回顧 1
1-2 奈米銀線反應機制與反應式 2
1-3 奈米銀線薄膜之回顧 4
1-4 奈米銀線感測器之回顧 5
1-5 研究動機及目的 6
第二章 實驗材料及實驗方法 7
2-1實驗藥品與儀器設備 7
2-1.1實驗藥品 7
2-1.2實驗儀器設備 7
2-2 實驗步驟 7
2-2-1製備Fe(NO3)3溶液及NaCl溶液前驅物溶液 7
2-2-2單杯放大五/二十五倍單次使用烘箱合成一/五/十杯並嘗試三種反應時間(14/30/100min) 8
2-2-3使用培養皿加大受熱面積合成二十五倍並嘗試兩種反應時間(25/50min) 8
2-2-4使用鐵盤加大受熱面積合成二十五倍並嘗試兩種反應時間(25/50min) 8
2-2-5合成完成的奈米銀線處理及檢測 9
2-2-6配置奈米銀線分散液 9
2-2-7使用抽氣過濾空氣乾燥的奈米銀線進行噴塗 9
2-2-8使用抽氣過濾氬氣乾燥的奈米銀線進行噴塗 9
2-2-9使用抽氣過濾未乾燥的奈米銀線進行噴塗及縮小玻璃片噴塗面積 10
2-2-10離心處理過程 10
2-2-11使用離心處理的奈米銀線進行噴塗 10
2-2-12 SR薄膜製備 11
2-2-13奈米銀線薄膜製備(SR基底) 11
2-2-14奈米銀線薄膜製備(SR基底) (大面積) 11
2-2-15 升溫測試實驗步驟 11
2-2-16人體手部加溫實驗步驟 11
2-2-17感測器製備 12
2-2-18 不同拉伸量的實驗步驟: 12
2-2-19 手指彎曲測試實驗步驟: 12
2-2-20眨眼測試實驗步驟: 12
2-2-21感測器熱退火處理實驗步驟 13
2-2-22脈搏測試實驗步驟 13
2-2-23感測器多點量測(吃東西情境)實驗步驟 13
2-2-24感測器量測腹式呼吸實驗步驟 13
2-2-25感測器多點量測(驚嚇情境)實驗步驟 13
2-2-26感測器判別食物軟硬度及辨別不同水溫實驗步驟 14
2-2-27具透明度的奈米銀線感測器應用測試步驟 14
第三章 結果與討論 15
3-1 奈米銀線合成 15
3-1-1 UV/Vis 奈米銀線長徑比預測表及XRD奈米銀線長徑比預測表的建立 15
3-1-2單杯放大五倍單次使用烘箱合成五杯並嘗試兩種反應時間(14/30min) 15
3-1-3單杯放大二十五倍單次使用烘箱合成一杯並嘗試一種反應時間(100min) 17
3-1-4單杯放大二十五倍單次使用烘箱合成十杯並嘗試一種反應時間(100min) 18
3-1-5使用培養皿加大受熱面積合成二十五倍並嘗試兩種反應時間(25/50min) 19
3-1-6使用鐵盤加大受熱面積合成二十五倍並嘗試兩種反應時間(15/30min) 20
3-1-7 奈米銀線合成成本計算及與市價做比較 21
3-2奈米銀線薄膜製備 22
3-2-1 使用抽氣過濾空氣乾燥的奈米銀線進行噴塗 22
3-2-2 使用抽氣過濾氬氣乾燥的奈米銀線進行噴塗 22
3-2-3 使用抽氣過濾未乾燥的奈米銀線進行噴塗 22
3-2-4 使用抽氣過濾未乾燥的奈米銀線進行噴塗 (縮小噴塗範圍) 23
3-2-5使用離心處理的奈米銀線進行噴塗 23
3-3奈米銀線薄膜升溫及用於手部加溫 24
3-3-1 奈米銀線薄膜不同電壓下的升溫(玻璃基底) 24
3-3-2 奈米銀線薄膜3V電壓下的升溫及用於人體手部加溫(SR基底) 24
3-3-3 奈米銀線薄膜3V電壓下(連接電池座)的升溫及用於人體手部加溫(SR基底) 25
3-3-4 奈米銀線薄膜15V電壓下的升溫及用於人體手部加溫(大面積) 25
3-4高透光奈米銀線感測器測試 26
3-4-1 感測器不同初始電阻下測量其透光率及不同拉伸量的電阻變化率 26
3-4-2 手指彎曲測試 27
3-4-3 眨眼測試 27
3-4-4 脈搏測試 27
3-4-5 將感測器進行熱退火處理以用來作為溫度感測器使用 27
3-4-6 感測器多點量測(吃東西情境) 28
3-4-7 感測器量測腹式呼吸 29
3-4-8感測器多點量測(驚嚇情境) 29
3-4-9感測器區別出食物軟硬度的不同 30
3-4-10 感測器區別出判別溫度不同的水 30
3-4-11具透明度的奈米銀線感測器應用 31
第四章 研究自評 32
第五章 結論 33
第六章 未來展望 34
參考文獻 35
圖片說明 41
圖片 50

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