博碩士論文 101282001 完整後設資料紀錄

DC 欄位 語言
DC.contributor物理學系zh_TW
DC.creator莊敏強zh_TW
DC.creatorMin-Chiang Chuangen_US
dc.date.accessioned2016-7-21T07:39:07Z
dc.date.available2016-7-21T07:39:07Z
dc.date.issued2016
dc.identifier.urihttp://ir.lib.ncu.edu.tw:88/thesis/view_etd.asp?URN=101282001
dc.contributor.department物理學系zh_TW
DC.description國立中央大學zh_TW
DC.descriptionNational Central Universityen_US
dc.description.abstract石墨烯是一種由碳原子組成的二維薄膜,其厚度僅有一層原子層厚。自從2004年 Geim和 Novoselov 用膠帶法從石墨中剝離出石墨烯後,使得石墨稀的研究有著飛躍性的成長。二維空間的限制使得石墨烯有著獨特的線性色散關係,使得石墨烯有高電子遷移率、高透光性、堅韌且富有可撓性。這些特性讓石磨烯有著豐富的應用潛力。然而,高品質的石墨烯在工業上難以大量製造,這也成了石墨烯應用的瓶頸。在眾多製造石墨烯的方法中,化學氣相沉積被認為是最有可能工業化的方法,其優點為容易大量製造且便宜。為了提升石墨烯在工業上的應用,有兩個重要的重要的關鍵:大量製造和提升石墨烯的品質。 化學氣相沉積的製造限制在於冗長的升溫及降溫時間,一種利用鹵素燈加熱的快速升溫系統可以大量節省製呈時間。然而用此方法生成的石墨烯單晶非常微小,僅有微米等級;另一方面,Rouff 的團隊利用氧化銅為基板可以成長出公分等級的石墨烯單晶,此方法大大提升了石磨烯的品質,可以達到近乎無缺陷的石墨烯。 我們的研究結合了上述兩種的方法來達成快速且高品質的石墨烯製程,其中,我們特別關心氧在化學氣相沉積中所扮演的角色以及動力學。我們利用JMAK模型來分析石墨烯成長的相變化,並且利用了凝態物理中常用的相關方程式來定量分析不同的化學氣相成長機制。 zh_TW
dc.description.abstractGraphene is a two dimension thin film consisted with carbon atoms in honeycomb ordered. Due to its unique band structure, graphene as unique electronic and material properties. Therefore graphene is expected to have great application potential in the future. However, it is still challenging to produce large amount and perfect graphene which is suitable for the application. This shortage limited the ceiling of the potential of graphene. Among all possible solution to produce large amount and defect-free graphene, chemical vapor deposition seems like to be the possible way to fabricate industry scale graphene. Three of the key issues in chemical vapor deposition is the time, cost and quality of graphene. First, nowadays it is the guarantee way to form large and perfect graphene in lower pressure chemical vapor deposition system. However, such a grain needs long growth time which is impossible to meet the needs of industry scale. Also, the long heating and cooling time for furnace decrease the throughput of graphene. Second, hot wall furnace waste unwanted heat into the environment which is not helpful for the chemical vapor deposition process. Third, the quality of graphene of CVD is comparing poorly with mechanical exfoliation. In order to suit above issues, rapid thermal chemical vapor deposition is considered. Although rapid thermal chemical vapor deposition is a low cost and fast production way to grow graphene, the graphene grain is small due to the non-equilibrium heating process. Recently this issue is solved by growing graphene on copper oxide. By exposing the oxygen on the defect on copper, rapid thermal chemical vapor deposition is able to grow large single crystal graphene. However, the underlying mechanism is still the shortage. In this work, we investigate the role of oxygen in graphene chemical vapor deposition on copper oxide. We find out the mechanism of the nucleation and growth process with oxygen exposure by extending the JMAK model into a non-equilibrium region to explain the initial situation of CVD process. The extending JMAK model is able to explain the increasing in nucleation rate. In addition, a correlation function analysis in traditional condensed matter physic is workable to quantify the spatial distribution and uniformity of Graphene Island. This analysis also points out the transition from carbon forming new grain at local nucleation site to joining larger cluster and coalescence after oxygen exposure. en_US
DC.subject石墨稀zh_TW
DC.subject化學氣相沉積zh_TW
DC.subjectgrapheneen_US
DC.subjectChemical vapor depositionen_US
DC.title氧化銅上的石墨烯在快速化學氣相沉積過程中的成核以及成長動力學zh_TW
dc.language.isozh-TWzh-TW
DC.titleNucleation and growth kinetics of graphene growth on copper oxide substrate in a rapid thermal chemical vapor deposition processen_US
DC.type博碩士論文zh_TW
DC.typethesisen_US
DC.publisherNational Central Universityen_US

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