Synthesis and characterization of copper telluride nanostructures

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研究生：	陳家宇 Chen, Chia Yu
論文名稱：	Synthesis and characterization of copper telluride nanostructures 碲化銅奈米結構物合成與鑑定
指導教授：	段興宇 Tuan, Hsing-Yu
口試委員:	黃暄益曾院介
學位類別：	碩士 Master
系所名稱：	工學院 - 化學工程學系 Department of Chemical Engineering
論文出版年：	2011
畢業學年度：	99
語文別：	中文
論文頁數：	62
中文關鍵詞：	碲化銅、奈米
相關次數：	點閱：3 下載：0
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我們經由有機熱溶劑合成碲化銅奈米粒子，並由熱注射法將奈米粒子成核與生長的過程分開，探討反應溫度、界面活性劑、前驅物改變對碲化銅奈米粒子的影響。藉由改變這些變因，我們可以合成粒徑8.3奈米、均一分散的碲化銅奈米粒子及表面較為粗糙的奈米管，並由XRD、SAED分析其晶體結構，TEM分析形狀、晶格，ICP分析元素成份，並進行晶格模擬確認為碲化銅奈米粒子。進一步分析其光學、電學等物性，在光學方面，碲化銅奈米粒子會隨著銅空缺使自由載子濃度增高，在近紅外光區出現表面電漿共振，並計算其莫耳消光系數；在電性方面，碲化銅奈米粒子也因為自由載子濃度較高，使電阻變小。在碲化銅奈米管方面，我們藉由分析不同反應時間的產物，來確認碲化銅奈米管的生長機制。

Cu2-xTe nanoparticles with narrow size distribution and nanotubes have been successfully synthesized by varying reaction conditions under thermal decomposition method. X-ray powder diffraction (XRD) spectra were recorded to verify the structure of as-prepared nanocrystals. The morphologies of the nanocrystals were observed under scanning electron microscopy (SEM). Inductively coupled plasma atomic emission spectroscopy(ICP-AES) were analysed to confirm the composition of the Cu2-x nanoparticles which is Cu1.76Te. High-resolution transmission electron microscopy (HRTEM) were employed to characterize the crystalline nature and growth direction of the as-obtained products. Experimental results have shown that the reaction temperature and types of surfactant would affect the morphology of the Cu2-xTe nanocrystals. The optical and electricity properties of Cu2-xTe nanoparticle were also investigated, clearly revealed the localized surface plasmon resonances and low electrical resistance. The possible formation mechanism for saw-tooth surface morphology nanotubes was put forward by analyzing the products in different reaction time.

第一章緒論............................................................................................1
1-1奈米材料..........................................................................................1
1-2奈米粒子於有機溶劑中合成..........................................................3
1-3奈米化合物形狀控制.......................................................................5
1-4碲化銅文獻回顧..............................................................................12
第二章 實驗步驟及分析方法.............................................................17
2-1實驗藥品.........................................................................................17
2-2實驗設計.........................................................................................18
2-3實驗步驟.........................................................................................19
2-4鑑定儀器…….................................................................................20
第三章 結果與討論.............................................................................21
3-1碲化銅奈米粒子反應變因討論.....................................................21
3-2碲化銅奈米粒子結構分析.............................................................28
3-3碲化銅奈米粒子物理性質分析.....................................................36
3-4碲化銅奈米管結構分析.................................................................45
3-5反應時間對碲化銅奈米管影響.....................................................49
3-6碲化銅奈米管反應機制.................................................................51
第四章 結論.........................................................................................57
第五章 參考文獻.................................................................................59

                                

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