臺灣博碩士論文加值系統

近年來，奈米粉體的各項特殊性質應用在高分子的研究上相當廣泛，其中奈米二氧化矽為網狀結構，具有相當好的機械性質、耐化學性質與耐熱性質，可作為高分子的補強或填充材料。而二氧化鈦因具有化學穩定性、無毒性、紫外線吸收及容易取得之優點，故應用性極具潛力。奈米高分子複合材料的透明性、剛性、氣體穿透率之改善、耐燃性、熱變形溫度等補強效率大於一般填充補強材料，且提升了原材料之氣體阻隔性能，使材料的吸濕性、耐化性提升。因此，本研究之主要目的在於對高分子Polyethylene Terephthalate (PET，寶特瓶)添加不同比例之奈米二氧化矽及二氧化鈦進行討論，並探討其結晶行為與微結構之變化，並測試其氣密性能、耐壓強度及對紫外線(UV)照射強度遮透能力，另以場發掃描式電子顯微鏡(FE-SEM)、穿透式電子顯微鏡(TEM)、X光粉末繞射儀(XRPD)、紫外-可見光譜儀(UV-Vis)、熱示差掃瞄卡量計分析儀(DSC)、動態機械分析儀(DMA)、傅利葉轉換紅外線光譜儀(FTIR)及感應耦合電漿質譜儀(ICP-MS)來鑑定分析高分子PET添加不同比例之奈米二氧化矽及二氧化鈦複合材料之特性及成分。
實驗主要部份包括：使用高分子PET，以不同比例之奈米二氧化矽及二氧化鈦添加量進行改質，使改質後的PET瓶增加其耐壓強度及對紫外線照射強度遮透能力提升；並以XRPD、FE-SEM、TEM來觀察其為結構之變化，再以UV-Vis、DSC、DMA、FTIR及ICP-MS來分析改質後之PET瓶其機械性質與熱性質變化。經XRPD測試發現煅燒後的P-25晶型較為顯著，而二氧化矽奈米粒子本身為非晶相結構無孔洞的存在，為一圓球狀之顆粒，但也因凝聚的因素，造成粒子間形成所謂的網狀結構，其奈米複合材料具有二氧化鈦銳鈦礦的晶相，而且發現在添加不同比例TiO2-SiO2時其訊號的強度也會有所改變。再經FE-SEM及TEM測試得知TiO2及SiO2粉末在未研磨時皆為聚集現象，奈米粒子粒徑分佈約在50 nm左右，研磨之後奈米粒子粒徑分佈約介於20 ~ 50 nm。此外，於紫外光的照射下發現其吸收波長有明顯地變化，而調配比例在2：8 ~ 8：2時紫外光吸收範圍能涵蓋市面常見啤酒之玻璃瓶，並且發現在比例5：5時吸收波長起始點可提前至440 nm。由DSC及DMA測試發現Tg、Tm、Tcc及貯存模數(Storage Modulus)等變化得知，添加適當比例的奈米TiO2/SiO2對PET之熱性質及機械性質有改善的效果，Tg及Tm均提升了3 ~ 5℃、Tcc也上升了14 ~ 21℃。因此，可推測PET瓶經添加奈米TiO2/SiO2無機氧化物後，可以達到改質之效果及目的，而且其耐熱溫度已超過啤酒殺菌溫度。由FTIR光譜分析得知隨著TiO2-SiO2添加量的增加，C=O (1700-1750 cm-1)、COO (1304 cm-1)及C-H (730-770 cm-1)吸收峰值卻隨著減少，表示TiO2-SiO2已與PET分子鏈產生結合。由ICP-MS分析得知改質後的PET瓶隨著奈米氧化物添加量的改變，其Tg點也隨著改變，進而亦影響銻原子溶出的速率。由XANES實驗數據分析結果可知奈米TiO2經添加不同比例SiO2後，並不會改變其價數(Ti4+)及晶型結構。由EXAFS之數據中顯示，未添加SiO2之TiO2其O的配位數為3.96 ± 0.05，Ti-O鍵長為1.96 ± 0.01 Å，而添加不同比例之SiO2後，由結構參數特性顯示，添加金屬會造成Ti配位數及鍵長的改變，可以證明奈米SiO2與奈米TiO2鍵結產生Si-O-Ti。
由氣密性測試可以發現，添加0、0.3及5%奈米TiO2-SiO2時，其壓力下降速率大小分別是0.3＜5＜0%，因此可推測PET經添加奈米TiO2-SiO2後，可以減緩氧氣的逸散。在相同吹瓶製程溫度下發現添加5%奈米TiO2-SiO2時，其PET瓶的透明度變差且呈現霧狀，尤其在拉伸度最大的頸部其厚度最薄且外皮觸感非常粗糙；觀察添加0.3%奈米TiO2-SiO2的PET瓶，其透明度良好但是略偏淡黃色，而且其外皮觸感光滑。因此可知PET經添加適當奈米TiO2-SiO2之後，外觀透明度上已經達到改質的效果及目的。

Recently, nanotechnology had been applied on polyethylene terephthalate (PET) synthesis processes. The SiO2 nanoparticles have good mechanics, acid-resisting, and heat-proof properties by their network structures. TiO2 nanoparticles also have excellent chemical stability, nontoxicity, and shadowing of the ultra-violet properties. Therefore, in this research, different ratio of TiO2 and SiO2 could reduce gas permeability, pressure-proof, and ultra-violet shadowing characteristics of PET bottles. Moreover, the physcochemical, crystal microstructures, and morphological properties of PET bottle chips were also determined by FE-SEM, XRPD, TEM, UV-Vis spectra, DSC/DMA, FTIR, and ICP-MS.
The XRPD patterns showed that the TiO2 ratio increased as the enhanced P-25 peaks, in contrast the SiO2 ratio increased as the reductive P-25 peaks. The diameter of TiO2/SiO2 nanoparticles without lapping measured by FE-SEM were 50 nm, on the contrary, after lapping the nanoparticles size were decreased to 20-50 nm. Meanwhile the ratios of TiO2/SiO2 (2:8 ~ 8:2) dopped into PET made the ultra-violet shadowing property of PET reach the extent of other commercial beer bottles. In addition, the ultra-violet absorption wavelength was shifted toword 440 nm when compared to other beer bottle merchandises at doped ratio 5:5 TiO2/SiO2 into PET. After doping TiO2/SiO2 into PET showed the value of Tg, Tm or Tcc and modulus properties were significantly improved. The value of Tg or Tm was raised about 3 ~ 5℃ and the one of Tcc was raised about 14 ~ 21℃ as determined by DSC and DMA techniques. Moreover, the increase of Tg, Tm or Tcc value made the heat-proof of PET bottles meet the Pasteurizer standard procedure. The FTIR spectra showed that the peak of C=O (1700-1750 cm-1), COO (1304 cm-1) and C-H (730-770 cm-1) were shifted when dopping ratio increased. The FTIR spectra indicated that the TiO2/SiO2 nanocomposites had been linked up into PET microstructures. From the ICP-MS analyses, with doping TiO2/SiO2 nanoparticles made the leaching temperture of Sb(III) ions increased from 50 to 70℃ and lower the leaching concentration of Sb(III) ions in nanaocompositive PET bottles. Without doping SiO2 into the TiO2 for PET bottles, the coordination numbers (CN) of Ti atom and crystal structure were not changed. Ti EXAFS spectra also indicated that the CN and the bond distances were 3.96 ± 0.05 and 1.96 ± 0.01 Å respectively. After doping different ratios of TiO2/SiO2 (1:9 ~ 9:1) into PET bottless, it showed that the CN and bond distances were notably changed. Moreover, it could prove the TiO2 and SiO2 nanoparticles were reacted and formed into Ti-O-Si bonding eventually.
After gas permeability test, with different doping ratios of TiO2/SiO2 nanoparticles into PET bottles showed that the minimum pressure drop ratio was 0.3%. In other words, it indicated that the TiO2/SiO2 nanocomposites had been linked up into PET microstructures strongly and well sealed off oxygen gases for the PET bottles. In addition, at the same temperature of injection molding process, with doping 0.3% TiO2/SiO2 nanoparticles into PET bottles, it made the degree of pellucidity or hand handle higher than that one of 5% and can meet the commercial standards of pellucidity and hand handle.

目 錄
頁次
摘 要…………………………………………………………………I
ABSTRACT…………………………………………………………….III
誌 謝..…………………………………………………………….…V
目 錄…… ………………………………………………………...VI
圖 目 錄…………………………………………………….…..……...XI
表 目 錄……………………...…………………………………….XVIII
前言………………………………………………………………………1
1.1 研究動機與目的…………………………………………………….2
1.2 研究方向…………………………………………………………….3
第二章 文獻回顧………………………………………………………5
2.1 聚酯聚合物……………………………………………...……....…..5
2.1.1 聚酯聚合物(PET)之簡介……………………………….…….5
2.1.2聚酯聚合物用途介紹………………………………………….7
2.1.3聚酯聚合物之優點…………………………………………….7
2.2聚酯聚合物合成之原理及方法………...…………………………...9
2.2.1 DMT法………………………………………………………..10
2.2.2 TPA法……………………………….……………………......11
2.3 聚合設備……….……………..…………………………….……...13
2.3.1 熔融縮聚合設備………………….………………………….13
2.3.1.1 縮聚反應………….……………………….……….....13
2.3.1.2 聚合反應………………………………………..….....13
2.3.1.3 生產PET技術條件分析……………………………..13
2.3.2 固態聚合設備………………..……..…………………....…..17
2.4 PET之形態學(Morphology)……………………………………….19
2.4.1 結晶形………….…..……………….….…………………….22
2.4.2 非結晶形……………...…………….…….………………….22
2.4.3 可結晶形………….…..………….………….……………….23
2.4.4 高分子結晶的必要條件及結晶動力學……....….………….24
2.4.5 結晶對聚合物物性之影響……………….…...……….....….25
2.5 PET的特性……………………….………….………………..........27
2.5.1 PET的物理性能...………………….….…………..………...28
2.5.2 PET的化學性能 ………………....….………………...........28
2.5.3 玻璃轉移溫度(Tg)...................................................................29
2.5.4 熔點溫度..………...……………….….………..…....…..…...32
2.6 製瓶計畫…………………………………………………….……..33
2.6.1 製瓶流程……………………….….…………………..…….33
2.6.2 PET酯粒乾燥…………………...….……………...………...33
2.6.3 射出成形Injection Molding...…….…...……………………37
2.7 奈米粒子之特性……………………………………...…………....40
2.7.1 影響奈米微粒性質之原因.....................................................40
2.7.2 奈米微粒之應用…………………….…..…………....……..43
2.7.3 奈米微粒之製備方法..............................................................45
2.7.4 二氧化鈦粉末特性及應用......................................................46
2.7.5 二氧化矽特性及應用..............................................................50
2.7.5.1 物理特性..........................................................................50
2.7.5.2 化學特性..........................................................................51
2.7.5.3 二氧化矽之應用..............................................................53
2.7.6銻(Sb)溶出說明...................................................................55
第三章 實驗設備及方法……………………………………………..57
3.1 實驗藥品………………………..………………………………….57
3.2 實驗設備………………………..………………………………….58
3.3 奈米級TiO2-SiO2微粒之製備…………...…..…………………....60
3.4 奈米級TiO2-SiO2懸浮液之調配………...….…..………….….…..60
3.5 特性分析與性質測試.......................................................................61
3.5.1 X-ray粉末繞射儀及樣品準備................................................61
3.5.2 穿透式電子顯微鏡與樣品配製..............................................63
3.5.3 場發射掃描式電子顯微鏡………...…….……………….….66
3.5.4 比表面積分析儀……………………....………………….….68
3.5.5 紫外-可見光譜儀………………………....………………….70
3.5.6 熱示差掃瞄卡量計分析儀…………….…...…………….….72
3.5.7 動態機械分析儀......................................................................77
3.5.8 傅立葉轉換紅外光譜儀..........................................................81
3.5.9 感應耦合電漿質譜儀..............................................................83
3.5.10氣密性試驗.............................................................................85
第四章 結果與討論………………………………………………......87
4.1 TiO2-SiO2粉體之XRPD分析……………………………………..87
4.2 場發掃瞄式電子顯微鏡分析(FE-SEM)…..……..………………..92
4.3 穿透式電子顯微鏡分析(TEM)………………....………………....98
4.4 比表面積分析....……………...……………..……..…..…….…...103
4.5 紫外-可見光譜分析(UV-Vis).……………..……..…..………......106
4.6 熱示差掃描卡量計分析(DSC).......................................................114
4.7 動態機械分析儀(DMA).................................................................130
4.8 傅立葉轉換紅外光線光譜儀(FTIR)分析......................................140
4.9銻(Sb)金屬溶出試驗-----ICP-MS分析...........................................143
4.10吹瓶後外觀比較及氣密性測試....................................................145
第五章 結論及未來研究方向............................................................146
5.1 結論……………...………………………………………………..149
5.2 未來研究方向…………………...………………………………..153
參考文獻................................................................................................154
附錄A…………………………………..…...………………………...175
附錄B………………………………..………………………...……...178


圖 目 錄
頁次
圖1.1 添加奈米TiO2/SiO2對PET材料特性提昇及其應用
之研究流程………………………………………..…………….4
圖2.1 熔融狀態聚合物切成15∼20 mg的小球….……………….….9
圖2.2 PET縮合聚合反應……………………………………….…....11
圖2.3 Lurgi-Inventa製程流程圖………………………………….….15
圖2.4 杜邦製程流程圖…………………………………………...…..16
圖2.5 固態聚合製程流程………………………………...……….....18
圖2.6 固態聚合製程反應器………………………………………....18
圖2.7 Keller褶曲鏈(Fold Chain)結構模型…………….…………....19
圖2.8 晶球成長過程………………………………….…………...….20
圖2.9 肉串結構(Shish-kebab Structures)模型……………….………21
圖2.10 PET在各結晶溫度下Tg與結晶化度………….…..…………31
圖2.11 結晶度X與Tg之關係…………..………………….……...…31
圖2.12 寶特瓶的製造流程………………………………………....…33
圖2.13 乾燥系統操作流程圖……………………………………..…..35
圖2.14 乾燥系統中PET的儲螬............................................................36
圖2.15 PET的乾燥機............................................................................36
圖2.16 射出成型機外觀(一)………..…………………….………..….37
圖2.17 射出成型機外觀(二)………….…………………….………...37
圖2.18 射出成型機內部結構………….……………….….………….38
圖2.19 射出成型後瓶胚形狀................................................................38
圖2.20 射出成型各點操作溫度流程....................................................39
圖2.21 (a)表面原子數佔全部原子數的比例和粒徑之間的關
係、(b)單一立方晶格結構的原子盡可能以接近圓(或
球)進行配置的超微粒模式........................................................43
圖2.22 銳鈦礦型二氧化鈦之各種立體透視........................................47
圖2.23 金紅石型二氧化鈦之各種立體透視........................................47
圖2.24 二氧化鈦之金紅石型及銳鈦礦型結晶組態............................48
圖2.25 當TiO2的粒徑下降到10 nm以下呈現光催化量子
效應............................................................................................49
圖2.26 當TiO2的粒徑在20-50 nm時較佳之遮蔽力...........................49
圖2.27 人工合成二氧化矽之主要型態................................................50
圖2.28 石英(Quartz, SiO2)彩色模型圖.................................................51
圖2.29 SiO2的晶體名稱和溫度範圍..................................................52
圖2.30 SiO2表面結構..........................................................................52
圖2.31 SiO2粒子的凝結機制..............................................................52
圖2.32 二氧化矽顆粒凝集和成長理論................................................53
圖3.1 縮聚合成反應PET實驗所使用反應器示意圖…….….…….58
圖3.2 固態聚合反應實驗所使用反應器示意圖................................58
圖3.3 瓶胚射出作業流程圖................................................................59
圖3.4 奈米級TiO2-SiO2微粒之製備實驗流程..................................60
圖3.5 奈米級TiO2-SiO2溶液之製備實驗流程………………….......60
圖3.6 X光繞設儀之基本原理…………………………………..…..62
圖3.7 X光繞射儀裝置........................................................................62
圖3.8 電子與物質作用所產生的訊號……………………….….…..65
圖3.9 穿透式電子顯微鏡之儀器裝置………………………............65
圖3.10 場發射掃描式顯微鏡之主要構造............................................67
圖3.11 FE-SEM儀器裝置...................................................................67
圖3.12 BET儀器裝置..........................................................................69
圖3.13 雙光紫外光-可見光光譜儀之結構...........................................71
圖3.14 雙光紫外光-可見光光譜儀儀器裝置.......................................71
圖3.15 熱示差掃瞄卡量計分析儀器裝置............................................72
圖3.16 水的三相變化............................................................................73
圖3.17 熱流式DSC剖面圖…………………………………….…......73
圖3.18 以水的變化為例說明溫度差的成因…………..………...…...74
圖3.19 補償式DSC剖面圖...................................................................75
圖3.20 一般金屬電阻抗隨溫度變化的特性........................................75
圖3.21 動態機械分析儀器裝置............................................................77
圖3.22 對樣品施予Sin波的應力時，樣品所回應的振幅
(Amplitude)及相角差...............................................................77
圖3.23 儲存模數與損失模數說明圖....................................................78
圖3.24 典型熱固型材料之DMA圖譜..................................................79
圖3.25 DMA的設計示意圖...................................................................80
圖3.26 傅立葉轉換紅外線光譜儀(FTIR)之實驗配置.........................82
圖3.27 傅立葉轉換紅外線光譜儀(FTIR)之儀器裝置.........................82
圖3.28 感應耦合電漿質譜儀(ICP-MS)結構示意................................84
圖3.29 Agilent 7500s感應耦合電漿質譜儀(ICP-MS)..........................84
圖3.30 未改質PET瓶氣密測試(I)........................................................85
圖3.31 未改質PET瓶氣密性測試(II)…………………………......….86
圖3.32 PET瓶氣密性測試水槽………………………...….…..….…86
圖4.1 TiO2-SiO2不同混合比例之XRD分析………………..…...….88
圖4.2 TiO2-SiO2不同混合比例於火焰反應器之XRD分析..............90
圖4.3 奈米TiO2-SiO2不同混合比例於500℃乾燥箱乾燥
之XRD分析..............................................................................91
圖4.4 二氧化矽粒子易產生聚集現象................................................93
圖4.5 觀察奈米SiO2(a)未研磨及(b)研磨後聚集之FE-SEM
分析............................................................................................94
圖4.6 未研磨時(a)SiO2及(b)TiO2皆為聚集現象約50 nm之
FE-SEM分析.............................................................................95
圖4.7 研磨5分鐘後TiO2-SiO2混合顆粒之FE-SEM分析..............96
圖4.8 商業化TiO2 (Dagussa P-25) TEM分析........……….………....98
圖4.9 高分子阻氣性結構分析............................................................99
圖4.10 火燄合成之奈米二氧化矽微粒TEM分析.............................100
圖4.11 PET添加奈米SiO2/TiO2之TEM分析..................................101
圖4.12 商業化TiO2 (Dagussa P-25)之紫外-可見光譜分析...............106
圖4.13 奈米TiO2:SiO2 = 1:9 ~ 9:1之紫外-可見光譜分析.................107
圖4.14 台灣啤酒之熟啤酒玻璃瓶(棕)之紫外-可見光譜分析..........108
圖4.15 台灣啤酒之生啤酒玻璃瓶(綠)之紫外-可見光譜分析..........109
圖4.16 台灣啤酒之熟啤酒玻璃瓶......................................................110
圖4.17 台灣啤酒之熟啤酒玻璃瓶樣品..............................................110
圖4.18 台灣啤酒之生啤酒玻璃瓶......................................................111
圖4.19 無添加奈米TiO2-SiO2之熱流型PET第一段DSC
分析…………………………………………….……….....…115
圖4.20 添加0.3%奈米TiO2-SiO2之熱流型PET第一段DSC
分析……………………………………………………..........116
圖4.21 添加5%奈米TiO2-SiO2之熱流型PET第一段DSC
分析……………………………………………………….…..117
圖4.22 無添加奈米TiO2-SiO2之熱流型PET第三段DSC
分析.........................................................................................118
圖4.23 添加0.3%奈米TiO2-SiO2之熱流型PET第三段DSC
分析..........................................................................................119
圖4.24 添加5%奈米TiO2-SiO2之熱流型PET第三段DSC
分析..........................................................................................120
圖4.25 無添加奈米TiO2-SiO2之補償式PET第一段DSC分析....121
圖4.26 添加0.3%奈米TiO2-SiO2之補償式PET第一段DSC分析..122
圖4.27 添加5%奈米TiO2-SiO2之補償式PET第一段DSC分析....123
圖4.28 無添加奈米TiO2-SiO2之熱流型PET第二段DSC分析......124
圖4.29 添加0.3%奈米TiO2-SiO2之熱流型PET第二段DSC分析..125
圖4.30 添加5%奈米TiO2-SiO2之熱流型PET第二段DSC分析.....126
圖4.31 無添加奈米TiO2-SiO2之PET DMA中tanδ分析...............131
圖4.32 添加0.3%奈米TiO2-SiO2之PET DMA中tanδ分析..........132
圖4.33 添加5%奈米TiO2-SiO2之PET DMA中tanδ分析.............133
圖4.34 無添加奈米TiO2-SiO2之PET DMA中Storage Modulus
分析…………………………………………………….……134
圖4.35 添加0.3%奈米TiO2-SiO2之PET DMA中Storage
Modulus分析..........................................................................135
圖4.36 添加5%奈米TiO2-SiO2之PET DMA中Storage
Modulus分析..........................................................................136
圖4.37 .PET聚酯中添加(a)0%、(b)0.3%及(b)5%之FTIR
光譜分析..................................................................................141
圖4.38 .(a)法國知名礦泉水瓶及(b)未改質PET耐熱瓶、(c)改
質(添加0.3% TiO2-SiO2)PET耐熱瓶、 (d)改質(添加
5% TiO2-SiO2)PET耐熱瓶之ICP-MS分析..........................143
圖4.39 (a)無添加、(b)添加0.3%、(c)添加5%，
奈米TiO2-SiO2之PET瓶氣密性測試..................................144
圖4.40 添加量為(a)5%及(b)無添加，奈米TiO2-SiO2之PET
瓶吹瓶後之外觀比較……………………………………...145
圖4.41 添加量為(a)5%及(b)0.3%，奈米TiO2-SiO2之PET瓶
吹瓶後之外觀比較………………………………………....146
圖4.42 添加量為(a)5%、(b)5%、(c)0.3%及(d)無添加，奈米
TiO2-SiO2之PET瓶吹瓶後之外觀比較………………….147
圖A.1 無添加奈米TiO2-SiO2之熱流型PET三段式DSC分析....171
圖A.2 添加0.3%奈米TiO2-SiO2之熱流型PET三段式DSC
分析.........................................................................................172
圖A.3 添加5%奈米TiO2-SiO2之熱流型PET三段式DSC
分析.........................................................................................173
圖B.1 無添加奈米TiO2-SiO2之PET DMA分析............................174
圖B.2 添加0.3%奈米TiO2-SiO2之PET DMA分析............................175
圖B.3 添加5%奈米TiO2-SiO2之PET DMA分析...............................176

表 目 錄
頁次
表2.1 寶特瓶相關專利總覽……...……………………………………6
表2.2 生產寶特瓶技術條件分析…………………………………….14
表2.3 奈米微粒尺寸與表面原子數、表面能量的關係.......................42
表2.4 奈米微粒的粒徑與比表面積，表面原子數比例，
表面能和一個粒子中的原子數的關係.....................................42
表2.5 傳統奈米微粒的應用範圍…………………………………….44
表2.6 傳統奈米粒子的製備方法…………………………………….45
表2.7 二氧化鈦晶型比較表………………………………………….48
表2.8 二氧化矽粉體之應用………………………………………….54
表2.9 三氧化二銻 Antimony Trioxide性質說明…………………..56
表3.1 實驗藥品名稱、化學式及其相關資料………………………...57
表4.1 不同煅燒溫度之奈米TiO2的比表面積……………………..103
表4.2 不同煅燒溫度之Scherrer Equation計算得到的
平均粒徑結果………………………………………………..104
表4.3 不同比例二氧化鈦-二氧化矽粉末之能隙……………….…112
表4.4 由熱流式DSC所測得PET樹脂之各熱力學數據..................127
表4.5 由補償式DSC所測得PET樹脂之各熱力學數據…………..128
表4.6 由DMA所測得PET樹脂之各熱力學數據…………………137
表4.7 由DMA所測得PET樹脂之各Modulus數據……………….138
表4.8 PET樹脂與TiO2-SiO2奈米複材的主要IR特性吸收峰…….140

1.陳佳飛，「食品容器及包裝用塑膠材質之塑化劑溶出研究」，碩士論文，陽明大學環境衛生研究所(2002)。
2.Kawamura C., Coating Resins Synthesized from Recycled PET, Prog. Org. Coat., 45(1), 185-191 (2002).
3.Sanches B.B., Comparative Techniques for Molecuar Weight Evaluation of Poly (Ethtlene Terephthalate) (PET), Polym. Test., 24(4), 688-693 (2005).
4.Choi Y.W., Effects of Waste PET Bottles Aggregate on the Properties of Concrete, Cement. Concrete. Res., 35(2), 776-781 (2005).
5.Awaja F., Injection Stretch Blow Moulding Process of Reactive Extruded Recycled PET and Virgin PET Blends, Eur. Polym. J., 41(1), 2614-2624 (2005).
6.Guo W., Low Temperature Solid-State Extrusion of Recycled Poly (Ethylene Terephthalate) Bottle Scraps, J. Appl. Polym. Sci., 102(2), 2692-2699 (2006).
7.Barriocanal C., J. Anal. Appl. Pyrol., 73(1), 45-51 (2005).
8.Awaja F., Injection Stretch Blow Moulding Process of Reactive Extruded Recycled PET and Virgin PET Blends, Eur. Polym. J., 41(1), 2624-2634 (2005).
9.Awaja F., Statistical Models for Optimisation of Properties of Bottles Produced Using Blends of Reactive Extruded Recycled PET and Virgin PET, Eur. Polym. J., 41(1), 2097-2106 (2005).
10.Incarnato L., Structure and Rheology of Recycled PET Modied by Reactive Extrusing, Polymer, 41(2), 6825-6831 (2000).
11.Torres N., Stude of Thermal and Mechanical of Virgin and Recycle Poly(Ethylene Terephthalate) before and after Injection Molding, Eur. Polym. J., 36(1), 2075-2080 (2000).
12.李書銘，「利用回收聚酯寶特瓶製程高分子量共聚(醯胺-酯)之方法研究」，碩士論文，逢甲大學紡織工程研究所(2001)。
13.安田武夫，「日本高分子工業發展趨勢」，DIR Research Institute, Inc. (1994)。
14.日本化學經濟研究所，「合成樹脂需要構造調查報告書」(1995)。
15.Field W.W. Beer Container, U.S. Patent 006666358B1, Dec. 23 (2003).
16.Field W.W. Beer Container, W.O. Patent 00/78665A1, Dec. 28 (2000).
17.Parkes S. A Container for Beer and Other Beverages, W.O. Patent 92/17376, Oct. 15 (1992).
18.德利奧得公司(美國)，「包覆之玻璃容器及其製造方法」，TW Patent 00079407, Aug. 01 (1986)。
19.Liu R.Y.F., Hu Y.S., Schiraldi D.A., Hiltner A., and Baer E., Crystallinity and Oxygen Transport Properties of PET Bottle Wells, J. Appl. Polym. Sci., 94(2), 671-677 (2004).
20.Bao L., Dorgan J.R., Knauss D., Hait S., Oliverira N.S., and Maruccho I.M., Gas Permeation Properties of Poly (Lactic Acid) Revisited, J. Membrane Sci., 285(1), 166-172 (2006).
21.Chng M.L., Xiao Y., Chung T.S., Toriida M., and Tamai S., The Effects of Chemical Structure on Gas Transport Properties of Poly(Aryl Ether Ketone) Random Compolymers, Polymer, 48(1), 311-317 (2007).
22.工業技術研究院化學技術研究所，奈米技術與應用(2002)。
23.James E.O.’Conner, PolyPhenylene Sulfide Ppultruded Trpe Composite Structures, SAMPE Quart. (1984).
24.Brandt W. Goldworthy, Thermoplastic Composites: The New Structural, Plast. World, 56 (1984).
25.陳世明，尖端熱塑性複合材料，強化塑膠廣用新知季刊，No.58 (1994.4)。http://www.materilsnet.com.tw/DocView.aspx?id=100.
26.張文吉，熱塑性複合材料，強化塑膠廣用新知季刊，No.13 (1997.9)。http://www.materilsnet.com.tw/DocView.aspx?id=100.
27.工研院化學工業研究所，熱塑性複合材料現況調查報告，http://itis.org.tw/pub/873/93/14/BookFile/14517~14524.PDF.
28.Edel’ man, I.S., Skorospelova, V.I., Stepanov, S.a., and Anistratova, N.A., Spectral and magnetooptical Properties of Potassium Aluminno-borate Gkasses Containing Iron and Manganese, Soviet J. Glass Phys. Chem., 9(4), 340-345 (1983).
29.洪永輝，「聚對苯二甲酸乙二酯/黏土及聚乙烯/黏土奈米高分子複合材料之製備及性質鑑定」，碩士論文，長庚大學化工與材料工程研究所(2003)。
30.Roberts A.P., Henry B.M., Sutton A.P., Grovenor C.R.M., Briggs G.A.D., Miyamoto T., Kano M., Tsukahara Y., and Yanaka M. Gas Permeation in Silicon-Oxide/ Polymer (SiOx/PET) Barrier Films: Role of the Oxide Latice, Nano-defects and Macro-defects, J. Membrane Sci., 208(2), 75-88 (2002).
31.Erlat A.G. and Spontak R.J., SiOx Gas Barrier Coating on Polymer Substrates: Morphology and Gas Transport Considerations, J. Phys. Chem. B., 103(4), 6047-6055 (1999).
32.Semyra V.B., Wolfgang J., and Carlos A.A., Amorphous Hydrogenated Carbon Flms as Barrier for Gas Permeation Through Polymer Films, Diam. Relat. Mater., 9(2), 1971-1978 (2000).
33.Mondal A.M. and Ilias S., Analysis of Numerical Instability in Single-stage Gas permeation, J. Membrane Sci., 262(1), 5-10 (2005).
34.Shirakura A., Nakaya M., Koga Y., Kodama H., Hasebe T., and Suzuki T., Diamond-like Carbon Films for PET Bottles and Medical Applications, Thin Solid Films, 494(1), 84-91 (2006).
35.Moyssiadi T., Badaka A., Kondyli E., Vakirtzi T., Savvaidis I., and Kontominas M.G., Effect of Light Transmittance and Oxygen Permeability of Various Packaging Materials on Keeping Quality of Low Fat Pasteurized Milk: Chemical and Sensorial Aspcts, Int. Dairy J., 14(3), 429-436 (2004).
36.Kotani Y., Matsuda A., Kogure T., Tatsumisago M., and Minami T., Effects of Addition of Poly(Ethylene Glycol) on the Formation of Anatase Nanocrystals in SiO2-TiO2 Gel Films with Hot Water Treatment, Chem. Mater., 13(1), 2144-2149 (2001).
37.Lee D. and Oyama S.T., Gas Permeation Characteristics of a Hydrogen Selective Supported Silica Membrane, J. Membrane Sci., 210(1), 291-306 (2002).
38.Semyra V.B., Wolfgang J., and Carlos A.A., Hydrogen Plasma Treament of Poly(Ethylene Terephthalate) Surfaces, Surf. Coat. Tech., 138(1), 256-263 (2001).
39.Boutroy N., Pernel Y., Rius J.M., Auger F., Bardeleben H.J.V., Cantin J.L., Abel F., Zeinert A., Casiraghi C., Ferrari A.C., and Robertson J., Hydrogenated Amorphous Carbon Film Coating of PET Bottles for Gas Diffusion Barriers, Diam. Relat. Mater., 15(2), 921-927 (2006).
40.Sakudo N., Shinohara T., Amaya S., Endo H., Okuji S., and Ikenaga N., Ion Implantation into Concave Polymer Surface, Nucl. Instrum. Meth. B., 242(1), 349-352 (2006).
41.Madocks J., Rewhinkle J., and Barton L., Packaging Barrier Films Deposited on PET by PECVD using a new High Density Plasma Source, Mat. Sci. Eng. B. Solid, 119(5), 268-273 (2005).
42.Sivaramakrishna V., Raspante F., Palaniappan A., and Pascall M.A., PET Bottles Seal Quality Testing using an On-Line Pressure Differential Detector, J. Food Eng., 80(1), 645-654 (2007).
43.Chng M.L., Xiao Y., Chung T.S., Toriida M., and Tamai S., The Effects of Chemical Structure on Gas Transport Properties of Poly(Aryl Ether Ketone) Random Copolymers, Polymer, 48(2), 311-317 (2007).
44.洪詮雅，「氧化矽超微粒子之製備研究」，碩士論文，成功大學 (1998)。
45.Kawamura C., Ito K., Nishida R., Yoshihara I., and Numa N., Coating Resins Synthesized from Recycled PET, Prog. Org. Coat., 45(1), 185-191 (2002).
46.Sanches N.B., Dias M.L., and Pacheco E.B.A.V., Comparative Techniques for Molecular Weight Evaluation of Poly(Ethylene Terephthalate)(PET), Polym. Test., 24(3), 688-693 (2005).
47.Choi Y.W., Moon D.J., Chung J.A., and Cho S.K., Effects of Waste PET Bottles Aggregate on the Properties of Concrete, Cement. Concrete. Res., 35(1), 776-781 (2005).
48.Awaja F. and Pavel D., Injection Stretch Blow Moulding Process of Reactive Extruded Recycled PET and Virgin PET Blends, Eur. Polym. J., 41(1), 2614-2634 (2005).
49.Guo W., Tang X., Yin G., Gao Y., and Wu C., Low Temperature Solid-State Extrusion of Recycled Poly (Ethylene Terephthalate) Bottle Scraps, J. Appl. Polym. Sci., 102(2), 2692-2699 (2006).
50.Barriocanal C., Ðiez M.A., and Alvarez R., PET Recycling for the Modification of Precursors in Carbon Materials Maunfacture, J. Anal. Appl. Pyrol., 73(1), 45-51 (2005).
51.Awaja F. and Pavel D., Statistical Models for Optimisation of Properties of Bottles Produced using Blends of Reactive Extruded Recycled PET and Virgin PET, Eur. Polym. J., 41(5), 2097-2106 (2005).
52.Incarnato L., Scarfato P. Maio L.D., and Acierno D., Structure and Rheology of Recycled PET Modified by Reactive Extrusion, Polymer, 41(2), 6825-6831 (2000).
53.Torres N., Robin J.J., and Boutevin B., Study of Thermal and Mechanical Properties of Vrgin and Recycled Poly(Ethylene Terephthalate) befor and after Injection Molding, Eur. Polym. J., 36(1), 2075-2080 (2000).
54.李書銘，「利用回收聚酯寶特瓶製成高分子量共聚(醯胺-酯)之方法研究」，碩士論文，逢甲大學紡織工程研究所(2001)。
55.陳哲欣，「PU塗枓用水性聚異氰酸酯」，高分子工業，99期，86-94 (2002)。
56.工業技術研究院，「高性能寶特瓶的應用現況及展望」http://iek.itro.org.tw/，產業經濟與資訊服務中心(2003)。
57.啤酒瓶抗衝擊和耐壓力檢測比較試驗結果http://www.jsxy.net/consumer/moban03.jsp?InfoID=9587。
58.陳協志，「聚酯奈米複合材料基板之製備與物性特性研究」，碩士論文，中興大學材料工程研究所(2003)。
59.呂紹臺，「高分子-黏土奈米複合材料的製備與其介電特性之研究」，碩士論文，中原大學化學系(2003)。
60.陳仕笳，「聚苯乙烯/蒙脫土有機無機奈米複合材料之研究」，碩士論文，中國文化大學材料科學與製造研究所(2002)。
61.葉嘉文，「以苯胺有機鹼催化溶膠-凝膠反應製備壓克力-二氧化矽奈米複合材料及其性質之研究」，碩士論文，中原大學化學系(2004)。
62.范孝明，「PU樹酯添加奈米SiO2/TiO2之性能提昇研究」，碩士論文，元智大學化學工程研究所(2004)。
63.邱方道，「聚對苯二甲酸乙二酯/新世代聚乙烯参合體結晶行為與機械性質探討」NSC89-2216-E-182-007，長庚大學化學與材料工程學系(2000)。
64.張豐志，「奈米高分子複合材料發展概況與趨勢」，交大友聲390期，13-20 (2002)。
65.歐珍方，「PET/clay奈米複合材料之研究」，勤益技術學院化學工程系(2002)。
66.鄭智宏，「寶特瓶熱充填飲料倒甁殺菌安全評估及衛生管理要點」，碩士論文，屏東科技大學食品科學系(2003)。
67.Miyamae T. and Nozoye H., Surface Characterization and Photochemical Behavior of Poly (ethylene terephtalate) and TiO2/Poly (ethylene terephtalate) Interface by using Sum-frequency Generation, J. Photoch. Photobio. A., 145(3), 93-99 (2001).
68.Kim H.K., Ju H.T., and Hong J.W., Characterization of UV-cured Polyester Acrylate Films Containing Acrylate Functional Polydimethylsiloxane, Eur. Polym. J., 39(2), 2235-2241 (2003).
69.Acierno D., Amendola E., Fresa R., Iannelli P., and Vacca P., Crosslinking Liquid Crystalline Polyesters with Allyl Group as Lateral Substituent:Thermal and UV Activation, Polymer, 41(1), 7785-7792 (2000).
70.Moura E.A.B., Ortiz A.V., Wiebeck H., Paula A.B.A., and Silva A.L.A., Effects of Gamma Radiation on Commercial Food Packaging Films—study of Changes in UV/VIS Spectra, Radiat. Phys. Chem., 71(3), 199-202 (2004).
71.Gamage N.J.W., Hill D.J.T., Lukey C.A., and Pomery P.J., Favtors Affecting the Photolysis of Polyester—Melamine Surface Coatings, Polym, Degrad. Stabil., 81(1), 309-326 (2003).
72.Chu S.Z., Inoue A., Wada K., Haneda H., and Awatsu S., Highly Porou (TiO2-SiO2-TeO2)/Al2O3/TiO2 Composite Nanostructures on Glass with Enhanced Photcatalysis Fabricated by Anodization and Sol-Gel Process, J. Phys. Chem. B., 107(2), 6586-6589 (2003).
73.Decker C., High-speed Curing by Laser Irradiation, Nucl. Instrum. Meth. B., 151(2), 22-28 (1999).
74.Zhu Z. and Kelley M.J., IR Spectroscopic Investigation of the Effect of Deep UV Irradiation on PET Films, Polymer, 46(4), 8883-8891 (2005).
75.Murakami T.N., Kijitori Y., Kawashima N., and Miyasaka T., Low Temperature Preparation of Mesoporous TiO2 Films for Efficient Dye-sensitized Photoelectrode by Chemical Vapor Deposition Combined with UV Light Irradiation, J. Photoch. Photbio. A., 164(3), 187-191 (2004).
76.Newsham K.K., Splatt P., Coward P.A.,Greenslade P.D., Mcleod A.R., and Anderson J.M., Negligible Influence of Elevated UV-B Radiation on Leaf Litter Quality of Quercus Robur, Soil Biol. Biochem., 33(2), 659-665 (2001).
77.Li J., Chen C., Zhao J., Zhu H., and Orthman J., Photodegradation of Dye Pollutants on TiO2 Nanoparticles Dispersed in Silicate under UV-VIS Irradiation, Appl. Catal. B: Environ., 37(2), 331-338 (2002).
78.Pern F.J. and Glick S.H., Photothermal Stability of Encapsulated Si Solar Cell and Encapsulation Materials Upon Accelerated Exposures, Sol. Energ. Mat. Sol. C., 61(1), 153-188 (2000).
79.Basher A.S., Khan M.A., and Idriss K.M., UV-cured Films of Epoxy, Polyester and Urethane Oligomers and Their Applications on Hessian Cloth(Jute), Radiat. Phys. Chem., 48(3), 349-354 (1996).
80.林建明，「耐隆6添加二氧化鈦微粒複合材之加工及物性研究」，碩士論文，台灣大學高分子工程學系(2002)。
81.許立成，「利用田口實驗進行沈澱法製備奈米二氧化矽粒子之探討」，碩士論文，元智大學化學工程研究所(2003)。
82.Hattori A., Shimoda K., Tada H., and Ito S., Photoreactivity of Sol-Gel TiO2 Films Formed on Soda-Lime Glass substrates: Effect of SiO2 Underlayer Containing Fluorine, Langmuir, 15(16), 5422-5425 (1999).
83.Kwon C.H., Kim J.H., Jung I.S., Shin H., and Yoon K.H., Preparation and Characterization of TiO2-SiO2 Nano-composite Thin Films, Ceram. Int., 29(2), 851-856 (2003).
84.Matsuda A., Matoda T., Kogure T., Tadanaga K., Minami T., and Tatsumisago M., Preparation of Titania Nanosheet-Precipitaed Coating on Glass Substrates by Treating SiO2-TiO2 Gel Films with Hot Water Under Vibrations, J. Sol-Gel Sci. Technol., 31(2), 229-233 (2004).
85.Bikiaris D., Karavelidis V., and Karayannidis G., A New Approach to Prepare Poly (ethylene Terephthalate)/Silica Nanocomposites with Increased Molecular Weight and Fully Adjustable Branching or Crosslinking by SSP, Macromol. Rapid Commun., 27(3), 1199-1205 (2006).
86.Fox B., Moad G., Diepen G.V., and Willing I., Characterization of Poly (Ethylene Terephthalate) and Poly(Ethylene Terephthalate) Blends, Polymer, 38(12), 3035-3043 (1997).
87.Croda PET Bottles Benefit from New Slip Additive, Plastics Additives and Compounding January/February (2005).
88.Khayet M., Nasef M.M., and Mengual J.I., Radiation Grafted Poly (Ethylene Terephthalate)-Graft-Polystyrene Pervaporation Membranes for Organic/Organic Separation, J. Membrane Sci., 263(4), 77-95 (2005).
89.Widen H. and Hall G., Sensory Characterization of Polyester-Based Bottle Material Inertness using Threshold Odour Number Determination LWT, 40(5), 66-72 (2007).
90.Chen S.Y. and Cahill P.J., Polymer-Phyllosilicate Nanocomposites and Their Preparation, C.A Patent 2266402, June. 14 (2002).
91.塑膠世界雜誌社3月號39-55 (1991)。
92.櫻井亮一，市川彌太郎，山下源太郎，有機合成化學協會誌，10，P33 (1975)。
93.Hutchinson G.A. and Lee R.A., Mold for Injection Molding Multilayer Preforms, U.S. Patent 006352426B1, Mar. 5 (2002).
94.Hutchinson G.A., Coated Polyester Preforms and Method of Making Same, U.S. Patent 006391408B1, May 21 (2002).
95.Akkapeddi M.K., Socci E.P., Kraft T.J., Worley D.C., and Brown C.V., Oxygen Scavenging Polyamide Compositions Suitable for PET Bottle Applications, U.S. Patent 006410156B1, Jun. 25 (2002).
96.Akkapeddi M.K., Socci E.P., Kraft T.J., Worley D.C., and Brown C.V., Oxygen Scavenging Polyamide Compositions Suitable for PET Bottle Applications, U.S. Patent 006610234B2, Aug. 26 (2003).
97.Akkapeddi M.K., Socci E.P., Kraft T.J., Worley D.C., and Brown C.V., Oxygen Scavenging Polyamide Compositions Suitable for PET Bottle Applications, U.S. Patent 006656993B2, Dec. 2, (2003).
98.Ghatta H.A. and Cobror S., Flexible Bottles of Polyester Resin, U.S. Patent 20040209022, Oct. 21 (2004).
99.Timothy K.G., Alston H.W., and Elliott T.M., Stabilized Polyester Fibers and Films, U.S. Patent 20040214984, Oct. 28 (2004).
100.Lee E.W., Steven N.C., Clifford M.T., and Joseph S.R., Polyester Bottle Resins having Reduced Frictional Properties and Methods for Making the Same, C.A. Patent 2431527, June 14 (2002).
101.食品工業研究所，「食品飲料用塑膠容器產品專題」，IT IS經濟部產業技術資訊服務推廣計畫(2000)。
102.Hyun S.S. and Hyun J.C., A Study on the Comparison of the Various Waste Management Scenarios for PET Bottles using the Life-cycle Assessment (LCA) Methodology, Resour. Conserv. Recycl., 27(5), 267-284 (1999).
103.路德維希，天津市化學纖維研究所，聚酯纖維化學與工藝學（上下冊），紡織工業出版社，1977-1978。
104.European Polymers, Laminations and Coatings Conference, TAPPI, 119~131 (1992).
105.陳忠吾，「對苯二甲酸乙二酯（PET）製程中二甘醇生成及其醇解反媵之動力研究」，博士論文，台灣大學化學工程研究所(1999)。
106.何曼君、陳維孝、董西俠，高分子物理，復旦大學出版社。
107.梁伯潤、屈鳳珍、潘利華、劉喜軍、吳承訓，高分子物理學（二），中國紡織出版社。
108.趙準山，姜膠東，吳大誠，譚敏韶，高分子物理學，中國紡織出版社(1995)。
109.Lepage J.L., Robert G., Beckerich P., and Perez G., Process for Manufacturing Hollow Articles, and the Hollow Articles, Preforms and Bottles Obtained by this Process, TW Patent 00562731, Oct. 11 (2002).
110.張志卿，「對苯二甲酸間苯二甲酸與乙二醇共聚酯結晶行為研究」，碩士論文，元智大學化學工程學系(1998)。
111.李育德，顏文義，莊祖煌，聚合物物性高立書局(1982)。
112.陳智仁，「聚對苯二甲酸乙二酯結晶形態」，碩士論文，元智大學化學工程研究所(2001)。
113.L.H. Sperling, Introduction to physical polymer science, 2nd Ed., Chap. 6, John＆Sons (1992).
114.Saville B.P., Rhodes M.B., and Helmsley D.A., Detection of Cryptosporidium Oocysts in Human Facal Specimens by an Indirect Immunofluorescence Assay with Minoclonal Antibodies, J. Clini. Microbio., 27(5), 1135-1136 (1989).
115.Misra A. and Stein R.S., Comparison of the Molecular Structures of Cytoplasmic and Mitochondrial Malate Dehydrogenase, Biochem. Soc. Tran., 17(2), 301-304 (1989).
116.Jabarin S.A., Crystallization Behavior of Poly(ethylene Terephthalate), Polym. Eng. Sci., 29(18), 1259-1264 (1989).
117.Wielgosz, Z., Boranowska, Z., and Janicka, K., Infra Red Spectroscopic Studies of Polycarbonates, Plaste Kautsch., 19(12), 902-904 (1972).
118.Antwerpen F.V. and Krevelen D.W.， Light-scattering method for investigation of the kinetics of crystallization of spherulites, J. Polym. Sci., 10(3), 2423 (1972).
119.莊世璋，「聚乙二醇-對苯二甲酸-間苯二甲酸共聚酯結晶形態」，碩士論文，元智大學化學工程學系(2003)。
120.塑膠成形材料，高分子工學講座Vol.5
121.周瑞美，「對苯二甲酸、乙二醇與丁二醇共聚酯結晶行為研究」，碩士論文，元智大學化學工程學系(1999)。
122.陳嘉政，「聚對苯二甲酸乙二酯/聚醚亞醯胺參合的相容性及結晶行為」，碩士論文，元智大學化學工程學系(1996)。
123.蔡福財http://www.or.com.tw/index_ch.htm.
124.Birringer R., Herr U., and Gleiter H., Nanocrystalline Materials：A First Report, JIM Trans. Suppl., 7(4), 43-49 (1986).
125.吳國卿、董玉蘭，「奈米粒子材料的觸媒性質」，化工資訊，第13期，42-46(1999)。
126.陳郁文，「奈米材料在觸媒上的運用」，化工，第5卷第5期，21-25 (1998)。
127.莊萬發編撰，「超微粒子理論應用」，復漢出版社(1995)。
128.蘇品書，「超微粒子材料技術」，復漢出版社(2001)。
129.曾茂盛、關長斌、徐甲強，「奈米材料導論」，學富文化，19-21 (2002)。
130.羅益興、丁晴，「奈米觸媒的製備與應用-2001材料奈米技術專刊」，工業技術研究院，134-139(2001)。
131.林正良，「化學工業科技人才培訓計畫—介面化學工業技術人才培訓：電子科技用介面化學應用原理(一)」，經濟部工業局(2002)。
132.吳漢標，陳翊民，「微波吸收材料性質分析與應用」，工業材料，128(1997)。
133.陳信宏，「奈米銀微粒之化學合成與應用研究」，碩士論文，國立清華大學化學工程研究所(2002)。
134.李宗銘，「異方性導電膠材料技術與應用」，工業材料147期(1999)。
135.魏碧玉，賴明雄，「奈米材料在光學上的應用及其製造法」，工業材料，153期(1999)。
136.Park S.D., Cho Y.H., Kim W.W., and Kim S.J., Understanding of Homogeneous Spontaneous Precipitation for Monodispersed TiO2 Ultrafine Powders with Rutile Phase Around Room Temperature, J. Solid State Chem., 146(6), 230-238 (1999).
137.Babcock J. R., Zehner R. W., and Sita L. R., A heterocumulene metathesis route to Cd[ESiMe3]2 and passivated CdE (E = S and Se) nanocrystals, Chem. Mater., 10(8),2027-2029 (1998).
138.陳鎮華，「逆微胞系統中製備超微粒子之研究」，碩士論文，成功大學化學工程研究所(1997)。
139.龐文琴，「超微細材料的製備—超微細材料與觸媒研討會論文集」，19-22 (1996)。
140.史宗淮，「微粉製程技術簡介」，化工，42期，28-33 (1995)。
141.John D.W. and Sommerdijk N.A.J.M., Sol-gel materials chemistry and applications, Gordon and Breach Sci. Publishers (2001).
142.Obuchi E., Sakamoto T., and Nakano K., Photocatalytic Decomposition of Acetaldehyde over TiO2/SiO2 Catalyst, Chem. Eng. Sci., 54(5), 1525-1530 (1999).
143.Ehrhardt H., Campbell S.J., and Hofmann M., Structural Evolution of Ball-Milled ZnFe2O4, J. Alloy Compd., 399(2), 255-260 (2002).
144.Upadhyaya C., Mishrab D., Vermaa H. C., Anandc S., and Dasc R.P., Effect of Preparation Conditions on Formation of Nanophase Ni-Zn Ferrites through Hydrothermal Technique, J. Magn. Magn. Mater., 260(2), 188-194 (2003).
145.Luo H.Y., Yue Z.X., and Zhou J., Synthesis and High-Frequency Magnetic Properties of Sol-Gel Derived Ni-Zn Ferrite-Forsterite Composites, J. Magn. Magn. Mater., 210(5), 104-108 (2000).
146.Lopez Perez J.A., Lopez Quintela M.A., Mira J., Rivas J., and Charles S.W., Advances in the Preparation of Magnetic Nanoparticles by the Microemulsion Method, J. Phys. Chem. B., 101(41), 8045-8047 (1997).
147.Hoffmann M.R., Martin S.T., Choi W., and Bahnemann D.W., Environmental Applications of Semiconductor Photocatalysis, Chem. Rev., 95(1), 69-96 (1995).
148.Zhang Z., Wang C.C.; Zakaria R., and Ying J.Y., Role of Particle Size in Nanocrystalline TiO2-based Photocatalysts, J. Phys. Chem. B., 102(52), 10871-10878 (1998).
149.Andersson M., Osterlund L., Ljungstrom S., and Palmqvist A., Preparation of Nanosize Anatase and Rutile TiO2 by Hydrothermal Treatment of Microemulsions and Their Activity for Photocatalytic wet Oxidation of Phenol, J. Phys. Chem. B., 106(41), 10674-10679 (2002).
150.Schimpf S., Lucas M., and Mohr C., Rodemerck U., Brückner A., Radnik J., Hofmeister H., and Claus P., Supported Gold Nanoparticles: In-depth Catalyst Characterization and Application in Hydrogenation and Oxidation Reactions, Catal. Today, 72(1-2), 63-78 (2002).
151.Ruys A.J. and Mai Y.W., The nanoparticle-coating process: A Potential Sol-gel Route to Homogeneous Nanocomposites, Mat. Sci. Eng. A-Struct., 265(1-2), 202-207 (1999).
152.Ryu J. and Choi W., Effects of TiO2 Surface Modifications on Photocatalytic Oxidation of Arsenite: the Role of Superoxides, Environ. Technol., 38(10), 2928-2933 (2004).
153.Cho Y., Choi W., Lee C.H., Hyeo T., and Lee H.I., Visible Light-induced Degradation of Carbon Tetrachloride on Dye-sensitized TiO2, Environ. Technol., 35(5), 966-970 (2001).
154.Choi W., Hong S.J., Chang Y.S., and Cho Y., Photocatalytic Degradation of Polychlorinated Dibenzo-ρ-dioxins on TiO2 Film under UV or Solar Light Irradiation, Environ. Technol., 34(22), 4810-4815 (2000).
155.Legrini O., Oliveros E., and Braun A.M., Photochemical Processes for Water Treatment, Chem. Rev., 93(2), 671-698 (1993).
156.Linsebigler A.L., Lu G., and Yates J.T., Photocatalysis on TiO2 Surface: Principles, Mechanisms, and Selected Results, Chem. Rev., 95(3), 735-758 (1995).
157.Tarr M. A., Wang W., Bianch T.S., and Engelhaupt E., Mechanisms of Ammonia and Amino Acid Photoproduction from Aquatic Humic and Colloidal Matter, Water Res., 35(15), 3688-3696 (2002).
158.Obuchi E., Sakamoto T., and Nakano K., Photocatalytic Decomposition of Acetaldehyde over TiO2/SiO2 Catalyst, Chem. Eng. Sci., 54(8), 1525-1530 (1999).
159.http://cst-www.nrl.navy.mil/lattice/struk.picts/c5.s.png.
160.http://cst-www.nrl.navy.mil/lattice/struk.picts/c4.s.png.
161.Beck J.S., Vartuli J.C., Roth W.J., Leonowicz M.E., Kresge C.T., Schmitt K.D., Chu C.T.W., Olson D.H., and Sheppard E.W., A New Family of Mesoporous Molecular Sieves Prepared with Liquid Crystal Templates, J. Am. Chem. Soc., 114(27), 10834-10843 (1992).
162.Chen J.C., Ollis D.F., Rulkens W.H., and Bruning H., Photocatalyzed Oxidation of Alcohols and Organochlorides in the Presence of Native TiO2 and Metallized TiO2 Suspensions. Part (I): Photocatalytic Activity and pH Influence, Water Res., 33(3), 661-668 (1999).
163.Bae E. and Choi W., Highly Enhanced Photoreductive Degradation of Perchlorinated Compounds on Dye-Sensitized Metal/TiO2 under Visible light, Environ. Technol., 37(1), 147-152 (2003).
164.Chen C., Zhao W., Li J., Zhao J., Hidaka H., and Serpone N., Formation and Identification of Intermediates in the Visible-light-assisted Photodegradation of Sulforhodamine-B Dye in Aqueous TiO2 Dispersion, Environ. Technol., 36(16), 3604-3611 (2002).
165.Klosek S. and Raftery D., Visible Light Driven V-doped TiO2 Photocatalyst and Its Photooxidation of Ethanol, J. Phys. Chem. B., 105(14), 2815-2819 (2001).
166.Li X., Chen C., and Zhao J., Mechanism of Photodecomposition of H2O2 on TiO2 Surfaces under Visible Lightirradiation, Langmuir, 17(13), 4118-4122 (2001).
167.Shivalingappa L., Sheng J., and Fukami T., Photocatalytic Effect in Platinum Doped Titanium Dioxide Films, Vacuum, 48(5), 413-416 (1997).
168.Nosaka Y., Koenuma K., Ushida K., and Kira A., Reaction Mechanism of the Decomposition of Acetic Acid on Illuminated TiO2 Powder Studied by Means of In-situ Electron Spin Resonance Measurements, Langmuir, 12(3), 736-738 (1996).
169.Kraeutler B. and Bard A.J., Heterogeneous Photocatalytic Synthesis of Mrthane from Acetic Acid-new Kolbe Reaction Pathway, J. Am. Chem. Soc., 100(7), 2239-2240 (1978).
170.Zhang D., Wang W., Liu Y., Xiao X., Zhao W., Zhang B., Cao Y., Photosensitization of Nanocrystalline TiO2 Electrodes by Squarylium Cyanine Incorporated with a Ruthenium Bipyridyl Complex, J. Photoch. Photobio. A., 135(2-3), 235-240 (2000).
171.Rong W., akai S.N., Fujishima A., Watanabe T., and Hashimoto K., Studies of Surface Wettability Conversion on TiO2 Single-crystal Surface, J. Phys. Chem. B., 103(12), 2188-2194 (1999).
172.Herman G.S., Dohnálek Z., Ruzycki N., and Diebold U., Experimental Investigation of the Interaction of Water Methanol with Anatase –TiO2(101), J. Phys. Chem. B., 107(12), 2788-2795 (2003).
173.Calzado C.J., Miguel San M.A., and Sanz J.F., Theoretical Analysis of K Adsorption on TiO2(110) Rutile Surface, J. Phys. Chem. B., 103(3), 480-486 (1999).
174.An Y.J., Jeoung S.W., and Carraway E.R., Research Note Micellar Effect on the Photolysis of Hydrogen Peroxide, Waer. Res., 35(13), 3276-3279 (2001).
175.許立成，「利用田口實驗進行沉澱法製備奈米二氧化矽粒子之探討」，碩士論文，元智大學化學工程學系(2002)。
176.莊萬發，超微粒子理論應用，復漢出版社(1995)。
177.蘇品書，’’超微粒子材料技術’’，復漢出版社，台南市(2001)。
178.Iler R. K., The Chemistry of Silica, John Wiley & Sons, New York (1979).
179.Tatterson G., Controlling Agglomeration in your Process, Chem. Process, North Carolina (2001).
180.郝士明，漫談晶體結構學─從材料學談起，政大印書館股份有限公司，台北市(1997)。
181.Degussa, Degussa Silicas for HTV Silicone Rubber, Tech. bull. pigments, No.12, Degussa AG (1994).
182.高分子工業，合成二氧化矽的特性與用途，高分子工業78，72-76(1998)。
183.Krysztafkiewicz A., Binkowski S., and Wysocka I., Pigments on Amorphous Silica Carriers, Powder Technol., 132(2), 190-195 (2003).
184.Degussa, Synthetic Silicas as a Flow Aid and Carrier Substance, Technical Bulletin Pigments No.31 5rd Ed., Degussa AG (1995).
185.Cullity B.D., Element of X-Ray Diffraction. 2nd Ed. Reading (Mass): Addison-Wesley, 1978.102.
186.Machida M., Norimoto K., and Watanabe T., The Effect of SiO2 Addition in Suoer-hydrophilic Property of TiO2, Photocatal. Mater. Sci., 34(4), 2569-2574 (1999).
187.余家國，趙修建，林立，「超親水TiO2/SiO2複合薄膜的製備與表徵」，無機材料學報(J Inorg. Mater.), 16(3), 529-534 (2001)。
188.Roberts, A.P., Henry, B.M., Sutton, A.P., Grovenor, C.R.M., Briggs, G.A.D., Briggs, G.A.D., Miyamoto, T., Kano, M., and Yanaka, M., Gas Permeation in Sillion-Oxide/ Polymer (SiO2/ PET) Barrier Films: Role of the Oxide Lattice, Nano-defects and Macro-defects, J. Membrane Sci., 208(1-2), 75-88 (2002).
189.張英詩，「奈米二氧化鈦光觸媒催化微粒之合成及其在有機廢水處裡應用」，碩士論文，元智大學化學工程學系(2003)。
190.洪詮雅，「氧化矽超微粒子之製備研究」，碩士論文，國立成功大學(1998)。
191.Li, X., Lin, Z., Cai, J., Scriven, L.E., and Davis, H.T., J Phys. Chem., 99(27), 10865-10878 (1994).
192.林靜宜，「巴斯德殺菌芒果汁求最適溫度與時間之探討」，屏東科技大學碩士論文(2000)。
193.http://food.doh.gov.tw/food_how/book_3_3.htm.
194.http://tw.knowledge.yahoo.com/question/?qid=1405122507042.
195.http://tw.knowledge.yahoo.com/question/?qid=1406072707621.
196.Greg Settembre, Using VPD ICP-MS to Monitor Trace Metals on Unpatterned Wafer Surfaces, MICRO (1998).
197.Takahashi J. and Youno K., Characterization of Trace Impurities in Silicon Wafers by High Sensitivity Reaction Cell ICP-MS (2003).
198.張士仁、陳順隆，「ICP-MS在半導體製程的應用」，科儀新知，第21卷1期(1998)。