新型炭材料
新型炭材料
신형탄재료
NEW CARBON MATERIALS
2010年
4期
241-247
,共7页
张法明%常江%伯克尔 伊博哈德
張法明%常江%伯剋爾 伊博哈德
장법명%상강%백극이 이박합덕
碳纳米管%表面修饰%溶解%结构稳定性%生物医学应用
碳納米管%錶麵脩飾%溶解%結構穩定性%生物醫學應用
탄납미관%표면수식%용해%결구은정성%생물의학응용
Carbon nanotubes%Surface modification%Dissolution%Structural stability%Biomedical applications
采用水溶性的聚乙烯醇修饰多壁碳纳米管表面,研究了聚乙烯醇修饰的碳纳米管在水浴摇床Tris-HCl缓冲溶液中的溶解过程.通过红外光谱,差示扫描量热仪,透射电镜及X光衍射的方法对聚乙烯醇修饰的碳纳米管在溶解过程中的显微结构变化进行了研究.结果表明:浸泡21d后,聚乙烯醇修饰的碳纳米管部分溶解于缓冲溶液,形成无定形碳碎片;但大部分碳纳米管没有溶解,仍然保持管状结构.揭示出聚乙烯醇修饰的碳纳米管的溶解过程为:碳-碳键在浸泡过程中发生断裂,碳纳米管的部分溶解产生了无定形碳碎片与残留纳米管层片,残留纳米管层片进一步溶解最终成为无定形碳.提出与讨论了聚乙烯醇修饰的碳纳米管在Tris-HCl缓冲溶液中可能的溶解机理是:修饰后的碳纳米管表面具有很多缺陷和断裂的碳键,在缓冲溶液中聚乙烯醇的溶解导致嫁接位置的碳管壁的碳原子的释放,最终导致其管状结构的破坏.
採用水溶性的聚乙烯醇脩飾多壁碳納米管錶麵,研究瞭聚乙烯醇脩飾的碳納米管在水浴搖床Tris-HCl緩遲溶液中的溶解過程.通過紅外光譜,差示掃描量熱儀,透射電鏡及X光衍射的方法對聚乙烯醇脩飾的碳納米管在溶解過程中的顯微結構變化進行瞭研究.結果錶明:浸泡21d後,聚乙烯醇脩飾的碳納米管部分溶解于緩遲溶液,形成無定形碳碎片;但大部分碳納米管沒有溶解,仍然保持管狀結構.揭示齣聚乙烯醇脩飾的碳納米管的溶解過程為:碳-碳鍵在浸泡過程中髮生斷裂,碳納米管的部分溶解產生瞭無定形碳碎片與殘留納米管層片,殘留納米管層片進一步溶解最終成為無定形碳.提齣與討論瞭聚乙烯醇脩飾的碳納米管在Tris-HCl緩遲溶液中可能的溶解機理是:脩飾後的碳納米管錶麵具有很多缺陷和斷裂的碳鍵,在緩遲溶液中聚乙烯醇的溶解導緻嫁接位置的碳管壁的碳原子的釋放,最終導緻其管狀結構的破壞.
채용수용성적취을희순수식다벽탄납미관표면,연구료취을희순수식적탄납미관재수욕요상Tris-HCl완충용액중적용해과정.통과홍외광보,차시소묘량열의,투사전경급X광연사적방법대취을희순수식적탄납미관재용해과정중적현미결구변화진행료연구.결과표명:침포21d후,취을희순수식적탄납미관부분용해우완충용액,형성무정형탄쇄편;단대부분탄납미관몰유용해,잉연보지관상결구.게시출취을희순수식적탄납미관적용해과정위:탄-탄건재침포과정중발생단렬,탄납미관적부분용해산생료무정형탄쇄편여잔류납미관층편,잔류납미관층편진일보용해최종성위무정형탄.제출여토론료취을희순수식적탄납미관재Tris-HCl완충용액중가능적용해궤리시:수식후적탄납미관표면구유흔다결함화단렬적탄건,재완충용액중취을희순적용해도치가접위치적탄관벽적탄원자적석방,최종도치기관상결구적파배.
Multiwalled carbon nanotubes(MWCNTs)were modified with a water-soluble poly(vinyl alcohol)(PVA)polymer(MWCNTs-PVA). The dissolution of the MWCNTs-PVA in Tris-HCl buffer solution was carried out in a shaking water bath by a soaking method. The microstructural changes of the MWCNTs-PVA during soaking was investigated using Fourier transform-infrared spectroscopy, differential scanning calorimetry, transmission electron microscopy, and X-ray diffraction. It is found that part of the MWCNTs-PVA was dissociated into amorphous carbonaceous debris, but most of tubular structures were retained after 21d of soaking. The dissolution process revealed that the C-C bonds of the MWCNTs-PVA were broken-down with the generation of carbonaceous debris and residual carbon nanotube la-yers, and the latter can be further dissociated into amorphous carbonaceous debris. A possible dissolution mechanism of the MWCNTs-PVA in the buffer solution was proposed and discussed. The surface modified MWCNTs have many defects and open C-C bonds on the surfaces of the CNTs. The dissolution of the PVA in the buffer solution leads to a release of carbon atoms on the outer surface of the MWCNTs. It results in a further rupture of the C-C bonds and destroys the tubular structure.
