多階孔洞結構材料的合成及其藥物傳遞與電化學電池上的應用

Hong-Yuan Lian; 連泓原

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/58037

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	吳嘉文
dc.contributor.author	Hong-Yuan Lian	en
dc.contributor.author	連泓原	zh_TW
dc.date.accessioned	2021-06-16T08:04:55Z	-
dc.date.available	2024-06-12
dc.date.copyright	2014-07-08
dc.date.issued	2014
dc.date.submitted	2014-06-27
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/58037	-
dc.description.abstract	本論文利用自蝕刻、硬模板法等技術，合成具有多階孔洞結構的材料：中空結構的微孔配位聚合物，以及巨孔碳材微米球。除了材料的合成，上述材料進一步地應用於生醫領域的藥物載體，以及電化學元件如鋰離子電池、葡萄糖燃料電池等。以下簡述各章節涵括的內容。第一章介紹奈米孔洞材料的分類與常見的製備方式，以及多階孔洞結構可提供的優勢，並在第二章回顧創造多階孔洞結構的合成方法。第三章為中空微孔配位聚合物（普魯士藍）的製備，並且作為藥物載體進行抑制癌細胞。粒子大小110 nm的普魯士藍介晶質，經過自蝕刻處理，於粒子內部創造80 nm大小的中空巨孔孔穴。此中空普魯士藍具有高生物相容性、酸鹼穩定性，並擔任藥物載體的角色。裝載的抗癌藥物順鉑大多陷入殼層的微孔縫隙，無法自載體釋出，但仍可利用粒子表面吸附的順鉑，與癌細胞的DNA進行交聯作用，有效地達成毒殺癌細胞之目的。第四章為巨孔碳材微米球的製備，並且評估作為鋰離子電池負極的表現。於乳液系統中利用揮發誘導自組裝技術，獲得氧化矽蛋白石微米球，並擔任硬模板，獲得孔徑260 nm的巨孔碳材微米球。巨孔碳材微米球提供大量的崁鋰位置，獲得1542.2 mAh/g的首次充電電容量，為石墨理論電容量的4.1倍。此外，電容量隨循環次數而上升，於第60次循環時，可逆電容量達到1478.4 mAh/g。結合巨孔結構與石墨化的優勢，相較於0.1C速率，於20C高速率下仍可保有254.5 mAh/g的電容量。第五章藉由低溫催化石墨化法，使巨孔碳材轉化成石墨相碳材，並將此巨孔石墨微米球作為觸媒擔體，應用於葡萄糖燃料電池。結合巨孔結構、石墨碳相等優勢，巨孔石墨微米球可作為一優秀擔體。在鈀粒子大小、含量相近的條件下，相較於商業化碳材（石墨塊材、XC72），巨孔石墨微米球擔體可獲得最高的電化學催化表面積。組裝成為葡萄糖燃料電池後，巨孔石墨微米球擔體獲得最高輸出功率是XC72的2倍、商業化石墨的11.8倍。第六章總結本論文各項實驗，並且提出建議事項。	zh_TW
dc.description.abstract	In this dissertation, techniques such as self-etching and hard template method were employed to synthesize materials with hierarchically porous structure, including microporous coordination polymer with hollow structure and macroporous carbon microballs. These synthesized porous materials were further applied in drug carrier, lithium-ion battery and glucose fuel cell. In chapter 1, classification and common synthesis of nanoporous materials, and advantages of hierarchically porous structure are introduced. In chapter 2, facile synthesis of materials with hierarchically porous structure is reviewed. In chapter 3, microporous coordination polymer (Prussian blue, PB) with hollow structure is synthesized and employed as drug carrier to load anti-cancer drug for killing tumor. PB mesocrystal with size of 110 nm went through self-etching to create a macorporous hollow interior with diameter of 80 nm. Hollow PB showed high biocompatibility and pH stability, and these properties assumed a potential drug carrier. Anti-cancer drug (cisplatin) got stuck in micropores tightly to reduce drug leakage in advance; even so, cisplatin adsorbed on the surface of hollow PB still performed cytotoxicity through cross-linking DNA of cancer cell. In chapter 4, macroporous carbon microballs (MCM) are synthesized and work as anode of lithium ion battery. At first, silica opal microballs were prepared through evaporation-induced self-assembly in emulsion, and then served as a hard template to obtain macroporous amorphous carbon microball (A-MCM) with pore diameter of 260 nm. A-MCM provided large number of storage sites for lithium, and obtained first charge capacity of 1542.2 mAh/g, which is around 4.1 times higher than theoretical capacity of graphite. In addition, reversible capacity of A-MCM climbed to 1478.4 mAh/g after 60 cyles. By synergistic effect of macroporous structure and graphitization (G-MCM), capacity still remained 254.5 mAh/g while rate changed from 0.1C to 20C. In chapter 5, macroporous graphite microballs (G-MCM) acted as catalyst support for glucose fuel cell. Taking advantage of macoporous structure and graphite phase, Pd@G-MCM exhibited the highest electrochemical active surface area among all electrocatalysts under similar Pd size and amount. Assembling as glucose fuel cell, G-MCM performed maximum power density 2 times higher than XC72 and 11.8 times higher than conventional graphite. In chapter 6, studies and suggestions in every chapter are summarized.	en
dc.description.provenance	Made available in DSpace on 2021-06-16T08:04:55Z (GMT). No. of bitstreams: 1 ntu-103-D99524012-1.pdf: 40938286 bytes, checksum: 8d17a0bd96700673e57281476e447105 (MD5) Previous issue date: 2014	en
dc.description.tableofcontents	第一章、前言 1 1.1 背景介紹 1 1.2 孔洞材料 2 1.2.1 微孔材料 2 1.2.2 中孔材料 7 1.2.3 巨孔材料 14 1.3 多階孔洞結構 19 1.4 論文大綱 20 第二章、文獻回顧 23 2.1 硬模板法（hard‐templating method） 23 2.2 軟模板法（soft‐templating method） 28 2.3 後處理法（post‐treatment） 29 2.4 自形成現象（self‐formation phenomenon） 32 2.5 多階孔洞擔體（hierarchically porous scaffolds） 33 2.6 化學氣相沈積法（chemical vapor deposition） 33 第三章、中空結構的微孔配位體奈米粒子之合成，及細胞內藥物傳遞之應用 34 3.1 背景介紹 34 3.2 研究動機 36 3.3 實驗方法 38 3.3.1 實驗藥品 38 3.3.2 實心普魯士藍奈米粒子的製備 39 3.3.3 中空普魯士藍奈米粒子的製備 39 3.3.4 藥物的體外吸附與釋放 39 3.3.5 細胞培養 40 3.3.6 細胞存活率分析 40 3.3.7 共軛焦螢光顯微鏡觀察 41 3.3.8 材料特性鑑定 41 3.4 結果與討論 43 3.4.1 材料鑑定與分析 43 3.4.2 材料生物相容性 49 3.4.3 藥物的吸附與釋放行為 51 3.4.4 毒殺癌細胞實驗 54 3.5 結論 57 第四章、巨孔無序�石墨碳材微米球的製備，及鋰離子電池之應用評估 58 4.1 背景介紹 58 4.2 研究動機 60 4.3 實驗方法 62 4.3.1 實驗藥品 62 4.3.2 巨孔碳材的製備 62 4.3.3 鋰離子電池組裝 64 4.3.4 電化學分析 65 4.3.5 材料特性鑑定 66 4.4 結果與討論 67 4.4.1 材料的鑑定與分析 67 4.4.2 充放電測試 82 4.4.3 長循環測試 87 4.4.4 循環伏安分析 90 4.4.5 交流阻抗測試 92 4.4.6 高速充放電實驗 94 4.5 結論 100 第五章、鈀奈米粒子�巨孔石墨微米球的製備，及葡萄糖燃料電池之應用評估 101 5.1 背景介紹 101 5.2 研究動機 103 5.3 實驗方法 105 5.3.1 實驗藥品 105 5.3.2 鈀奈米粒子修飾於碳材 105 5.3.3 電化學分析 106 5.3.4 葡萄糖燃料電池效能測試 107 5.3.5 材料特性鑑定 107 5.4 結果與討論 109 5.4.1 材料的鑑定與分析 109 5.4.2 電化學活性表面積 117 5.4.3 電化學催化葡萄糖氧化反應 118 5.4.4 葡萄糖燃料電池 121 5.5 結論 123 第六章、總結與展望 124 6.1 研究總結 124 6.2 未來展望 125 參考文獻 128 作者履歷 151
dc.language.iso	zh-TW
dc.subject	藥物載體	zh_TW
dc.subject	巨孔碳材微米球	zh_TW
dc.subject	普魯士藍	zh_TW
dc.subject	多階孔洞結構	zh_TW
dc.subject	葡萄糖燃料電池	zh_TW
dc.subject	鋰離子電池	zh_TW
dc.subject	glucose fuel cells	en
dc.subject	Prussian blues	en
dc.subject	macroporous carbon microballs	en
dc.subject	drug carriers	en
dc.subject	lithium ion batteries	en
dc.subject	hierarchically porous structures	en
dc.title	多階孔洞結構材料的合成及其藥物傳遞與電化學電池上的應用	zh_TW
dc.title	Synthesis of Hierarchically Porous Materials for Drug Delivery and Electrochemical Cells	en
dc.type	Thesis
dc.date.schoolyear	102-2
dc.description.degree	博士
dc.contributor.oralexamcommittee	廖英志,康敦彥,陳林祈,劉偉仁
dc.subject.keyword	多階孔洞結構,普魯士藍,巨孔碳材微米球,藥物載體,鋰離子電池,葡萄糖燃料電池,	zh_TW
dc.subject.keyword	hierarchically porous structures,Prussian blues,macroporous carbon microballs,drug carriers,lithium ion batteries,glucose fuel cells,	en
dc.relation.page	154
dc.rights.note	有償授權
dc.date.accepted	2014-06-27
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	化學工程學研究所	zh_TW
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