当材料的尺寸减小到100nm时，量子化学和经典物理理论不再适用，导致材料出现了一些重要的效应和新的性质。因此纳米科学在最近20年间一直是多学科交叉的前沿研究领域，无论是在应用还是基础研究方面都吸引了大量的关注和兴趣。尤其是不同的纳米材料组成纳米复合材料后巨大应用前景，纳米科学和生物科学的结合更是在今年成为研究的热点。本论文工作主要分为两部分，其一是生物纳米复合材料的制备及其在催化、生物传感器方面的应用；其二是特殊形貌和表面结构的贵金属纳米粒子与合金纳米粒子的合成，及运用透射电子显微镜原位研究纳米粒子的生长过程、并指导其形貌控制合成。主要内容和结果如下： 1、制备了氧化石墨烯/十六烷基三甲基溴...When the size of materials reduced to below 100 nm, both quantum chemistry and classical laws of physics are not suitable, which lead to novel and important properties, are unavailable in conventional materials and devices. Nowadays, the studies of nanomaterials have become an active foreland field of multidisciplinary and arisen scientists’ swinging interests and extensive attentions on both fund...学位：理学博士院系专业：化学化工学院化学系_物理化学(含化学物理)学号：2052007015360

廖洪钢

Xiamen University Institutional Repository

学校编码：10384 学号：20520070153603         博  士  学  位  论  文         纳米粒子生长机理研究及生物纳米复合材料的制备及应用研究         Investigation of Growth Mechanism ofNanocrystals and Fabrication andApplication of Bionanocomposite Materials         廖洪钢         指导教师：孙世刚     林跃河            专业名称：物理化学(含化学物理)         答辩日期：2012年7月   厦门大学博硕士论文摘要库厦门大学学位论文原创性声明                  本人呈交的学位论文是本人在导师指导下,独立完成的研究成果。本人在论文写作中参考其他个人或集体已经发表的研究成果，均在文中以适当方式明确标明，并符合法律规范和《厦门大学研究生学术活动规范(试行)》。                  另外，该学位论文为(                  )课题(组)的研究成果，获得(                    )课题(组)经费或实验室的资助，在(          )实验室完成。(请在以上括号内填写课题或课题组负责人或实验室名称，未有此项声明内容的，可以不作特别声明。)                           声明人(签名)：                            年   月   日厦门大学博硕士论文摘要库厦门大学学位论文著作权使用声明                  本人同意厦门大学根据《中华人民共和国学位条例暂行实施办法》等规定保留和使用此学位论文，并向主管部门或其指定机构送交学位论文(包括纸质版和电子版)，允许学位论文进入厦门大学图书馆及其数据库被查阅、借阅。本人同意厦门大学将学位论文加入全国博士、硕士学位论文共建单位数据库进行检索，将学位论文的标题和摘要汇编出版，采用影印、缩印或者其它方式合理复制学位论文。                  本学位论文属于：                  (     )1.经厦门大学保密委员会审查核定的保密学位论文，于年 月 日解密，解密后适用上述授权。                  (     )2.不保密，适用上述授权。                  (请在以上相应括号内打“√”或填上相应内容。保密学位论文应是已经厦门大学保密委员会审定过的学位论文，未经厦门大学保密委员会审定的学位论文均为公开学位论文。此声明栏不填写的，默认为公开学位论文，均适用上述授权。)                           声明人(签名)：                            年   月   日厦门大学博硕士论文摘要库摘  要                  当材料的尺寸减小到100 nm时，量子化学和经典物理理论不再适用，导致材料出现了一些重要的效应和新的性质。因此纳米科学在最近20年间一直是多学科交叉的前沿研究领域，无论是在应用还是基础研究方面都吸引了大量的关注和兴趣。尤其是不同的纳米材料组成纳米复合材料后巨大应用前景，纳米科学和生物科学的结合更是在今年成为研究的热点。本论文工作主要分为两部分，其一是生物纳米复合材料的制备及其在催化、生物传感器方面的应用；其二是特殊形貌和表面结构的贵金属纳米粒子与合金纳米粒子的合成，及运用透射电子显微镜原位研究纳米粒子的生长过程、并指导其形貌控制合成。主要内容和结果如下：1、制备了氧化石墨烯/十六烷基三甲基溴化铵/室温离子液体纳米复合薄膜 (FGS /CTAB / RTIL)，并以其为载体组装肌红蛋白。由于FGS / CTAB / RTIL良好的生物兼容性，亲水性质及大的表面积，使得其保持了极好的蛋白生物活性，同时离子液体的存在加强了肌红蛋白与电极间的导电性。石墨烯表面的功能基团有利于蛋白的组装，加入室温离子液体后，更促进了蛋白与石墨烯，电极间的电子传输，以复合物膜制备的电极对双氧水具有极好的催化活性，作为双氧水传感器具有极低的检测限和较高的浓度检测范围。研究结果表面石墨烯是一种良好的第三代生物传感器蛋白的修饰载体，在新型生物传感器的应用中具有重要作用。2、用氯金酸为前躯体，采用化学还原的方法在低温共融物中合成了金纳米珊瑚，并将细胞色素C组装到其表面。以组装细胞色素C的金纳米珊瑚所制备的电极具有极好的电化学响应，远超目前文献所报道，结果证明纳米珊瑚的笼状结构，对促进蛋白与金基底间的电子传输有极大的作用，并且能很好的长时间保持蛋白的活性，是理想的生物传感器蛋白载体。进一步地以铁蛋白为模板采用化学还原法合成了壳厚度可控铁蛋白@金纳米壳结构，具有可调的近红外吸收性质，将可应用到细胞成像和癌症的光热疗法中。以去铁铁蛋白为模板合成了金纳米团簇，具有近红外荧光发光性质，可应用到不需要无标记物的高灵敏度、高选择性的生物传感器中。3、发展了一种以导电聚合物（PDDA）作为还原剂和稳定剂的简便绿色的方法制备出了水溶性的石墨烯。透射电镜、X-射线衍射和原子力显微镜证明所合成的石墨烯厦门大学博硕士论文摘要库是单层的，同时导电聚合物还有使纳米粒子单分散的作用，因此我们实现了在石墨烯上原位生长高分散的铂纳米粒子，形成石墨烯/铂纳米复合材料，该材料对甲酸氧化表现出极好的催化性能。同时通过还原法在石墨烯表面制备了单分散的钯，金钯合金粒子，相比与同样方法制备的粒子负载在碳黑载体上所得的纳米复合材料具有较好的甲酸氧化催化性能和更高的稳定性。研究表明石墨烯是一种非常有潜力的催化剂载体。4、金和金@钯纳米晶体在低温共融物（DES）中的形貌控制合成。以低温共融物为溶剂采用抗坏血酸为还原剂通过控制合成的温度，低温共融物中水含量，还原剂浓度等条件，合成得到了具有高指数晶面和非常规形状的金纳米粒子和金铂核壳结构的纳米粒子，极大的丰富了形貌控制合成并且有益于深入研究表面结构与性能间的联系规律。5、运用原位透射电镜实时观察了金纳米粒子在溶液中的生长过程，并研究其生长机理。原位透射电镜研究获得了非原位实验不可能获得的纳米粒子生长过程的重要信息，对深入理解纳米晶体的合成有重要的作用。包括以下几方面a. 首次通过原位透射电镜观察了五重孪晶的形成过程和方式。五重孪晶星形金纳米粒子的生长过程中，在开始生长和中后期生长中，每一个孪晶块因为尺寸和表面结构的不同可以采用连续生长或层生长模式。同时对于整个孪晶粒子，可以由孪晶晶种逐渐生长也可一块一块孪晶块生长，或者是由粒子聚合直接重构成五重孪晶。b. 纳米粒子生长过程中在溶液中的聚合。通过观察发现聚合时首先在两个粒子间生成一个连接的颈部，两个粒子以不同取向连接到一起，然后粒子通过结构重构和弛豫，或者重结晶来完成结构调整，最后生成一个单晶粒子，而不是通过同晶向的附着连接，直接聚合为单晶。对纳米粒子的结构和形貌演化的直接观察，极大的促进了对纳米粒子生长和结构控制的机理研究。c. 首次原位观察到了纳米粒子的奥氏熟化过程。通过观察纳米粒子的在溶液中的奥氏熟化过程，发现小粒子的溶解速度是一个加速过程，尺寸越小，溶解越快，大粒子的生长则基本是匀速，且小粒子的溶解速度受到环境的影响会有所波动。这项研究将对催化剂合成的粒径控制和抗老化研究有重要的指导作用。本论文发展了纳米粒子结构控制合成及纳米复合材料的合成方法，成功地制备出多厦门大学博硕士论文摘要库种高指数晶面的纳米晶体，并制备多种纳米复合材料，并将其应用到催化和生物传感器领域。并通过新颖原位TEM方法实时观察了纳米材料的生长过程，对纳米材料生长的许多重要问题提供了新的认识和解决的途径。本研究所发展的合成方法，为实现在原子或分子水平层次设计结构规整、高活性的催化剂和传感器打下了基础，具有重要的理论意义和应用价值。         关键词：石墨烯 ；肌红蛋白； 纳米晶体； 形状控制合成； 原位透射电镜；厦门大学博硕士论文摘要库Abstract                  When the size of materials reduced to below 100 nm, both quantum chemistryand classical laws of physics are not suitable, which lead to novel and importantproperties, are unavailable in conventional materials and devices. Nowadays, thestudies of nanomaterials have become an active foreland field of multidisciplinaryand arisen scientists’ swinging interests and extensive attentions on bothfundamental research and applications. Furthermore, when differentnanomaterials assembled to nanocomposite materials or when biomaterialsincorporate on to nanomaterials have wide applications and attract huge interests.The synthesis and control of materials in nanometer dimensions can access newmaterial properties and device characteristics in unprecedented ways. Thus, thisthesis focuses primarily on two parts: 1) nanocomposite materials preparation andapplication in catalysis and biosensor. 2) Shape and surfaces structure control ofnanomaterials, and use in-situ TEM to investigate the growth kinetics of noblemetal nanoparticles.The main results are as follows.1. We have explored FGS/CTAB/RTIL nanocomposite film as a support matrix forimmobilizing Mb. The prepared nanocomposite film can effectively retain theactivity of entrapped Mb because of its biocompatibility, hydrophilic environment,and large specific surface area. Surface functional groups of the graphene alsoplay an important role in bonding Mb. The electrochemical behaviors of themodified electrode suggest that graphene can provide a favorablemicroenvironment for MB, and RTIL can improve the direct electron transfer at theelectrode surface. In addition, the MB/nanocomposite films perform good catalyticreactivity to H2O2. The Mb/graphene-based H2O2 sensor has a low detectionlimit and a satisfactory linear range. The present study suggests that graphene isan excellent transducing material for immobilizing proteins to fabricate third-厦门大学博硕士论文摘要库generation biosensors. It shows potential for immobilizing other biologically activematerials on these kinds of nanosheets for constructing novel biosensors.2. A novel gold nanocorals was synthesized by reducing HAuCl4 in deep eutecticsolvent(DES); the unique cage structures of nanocorals greatly promote theelectron transfer between cyt c and gold and could keep the activity of cyt cforlong time. The electrodes modified by the mixed nanocomposite materials wereshown to have fine-tuned reproducible quasi-reversible electrochemistry of cyt c.The modified electrodes showed the high stability and reproducibility as well asan excellent electron transfer promotion characteristics for cyt c, providing highand reproducible current responses as evidenced by better defined CV shapesthan any other reported to our knowledge. We have synthesized gold nanoshellsand with adjustable thickness and NIR absorption properties by using ferritin astemplate, which may have wide application in cell image or caner thermal therapy.With this method to could also synthesize highly fluorescent gold clusters byusing apoferritin as template, which can be used for highly sensitive and selectivelabel free sensor.3. We have developed a green and facile approach to prepare soluble graphenenanosheets. The key is the introduction of a positively charged polyelectrolyte,PDDA, which acts as both a reducing agent and a good stabilizer during theformation of graphene nanosheets. Another important role of PDDA is to facilitatethe uniform deposition of metal nanoparticles on graphene nanosheets. Pt, Pd,PtAu alloy NPs on graphene were prepared with a uniform dispersion via apolyelectrolyte-assisted process. They exhibited highly electrocatalytic activityand stability for formic acid oxidation. The finding is of significance for theapplication of graphene because polyelectrolytes can faciliate the uniformdisperson of metal NPs on graphene, which has been demonstrated as apromising anode electrocatalyst of direct formic acid fuel cells. Moreover, thisfacile preparation method can be readily extended to the synthesis of other noble厦门大学博硕士论文摘要库metal NPs. We therefore expect that our findings will lead to the furtherdevelopment in preparation of high-quality graphene nanosheets and graphene-based nanocomposite, which may significantly facilitate the application ofgraphene in fuel cells and other fields.4. We achieved shape-control synthesis of gold NPs without using anysurfactants and seeds but employing DES as solvent. Star-shape gold NPs thatare bounded with high-index (331) were successfully synthesized for the firsttime. It has also illustrated that Au and Au/Pd NPs of various shape and surfacestructure can be obtained just by adjusting the content of water, reactiontemperature, or precursor concentrations in the DES. The variety in shape offersopportunity to change the surface structure of nanoparticles and examine thestructure-functionality in electrocatalysis. The work of minimizing Au NPs’ sizehas been also conducted, and our preliminary results demonstrated that smallerstar-shape gold NPs could be synthesized by adding Au seeds. The presentmethod may be also applied to carry out shape-control synthesis of other metalNPs.5. We have observed the dynamic growth of single colloidal gold nanocrystals inDES solution with an in situ TEM. This observation reveals much importantinformation about colloidal nanocrystal growth and is very beneficial in developinga detailed understanding of growth mechanisms and the precise control ofnanoparticle’s growth with desired shape and properties. Moreover, this in situTEM observation based on DES is a convenient and low-cost method which couldhave great potentials for addressing many fundamental issues in materialsscience, chemistry, and other fields of science.a) We directly observed the growth of individual five-fold nanocrystal in a eutectic-based ionic liquid solution with in situ transmission electron microscopy (TEM).The observation depicts much important information regarding five-fold twinnednanocrystal growth. In single fivefold star-shaped nanocrystal, the five branches厦门大学博硕士论文摘要库can adopt different growth mechanisms at different growth stage, due to the sizeand structure difference. The coalescence-based growth is also an importantmechanism for multi-twinned nanocrystal’s formation in solution. This is of greatsignificance for fully understanding the growth mechanism and controlling of thegrowth of colloidal nanocrystal.b)The particle’s coalescence in solution is not through an oriented attachment-based growth, but rather, generates necks first and then through a grain rotationand a recrystallization process to form a single crystal. During the growth andshape evolution process many dislocations and stacking faults were generated.This may be of great help for us to fully understand the colloidal nanocrystalshape and structure evolution mechanism.c) The nanoparticle’s Ostwald ripening was observed by in situ TEM for the firsttime, and the quantitive data get form the observation will help to understandmany fundamental issues of colloidal chemistry and materials science.In this thesis we developed a novel method to synthesize nanocrystal andnanocomposite materials. Break through the limit of conventional chemicalmethod, NPs bounded with high-index facets were successfully synthesized;nanocomposite materials was prepared, and applied in catalysis and biosensor.We observed the real time growth process of nanocrystal in liquid by using in-situTEM and get important information about nanocrystal growth that cannot get fromex-situ experiment. The method developed in this thesis will support the design ofcatalyst and biosensor at atom scale, and it is also an important progress from thefundamental research to application, which will have great influence in researchand economy.         Keywords: Nanocomposite materials; Nanocrystals; Shape-controlled synthesis;Biosensor; In-situ TEM厦门大学博硕士论文摘要库参考资料         1 Ding, R. G., Lu, G. Q., Yan, Z. F. & Wilson, M. A. Recent advances in the preparation and utilization ofcarbon nanotubes for hydrogen storage. Journal of Nanoscience and Nanotechnology 1, 7-29,doi:10.1166/jnn.2001.012 (2001).2 Pang, L. S. K. et al. Competitive reactions during plasma arcing of carbonaceous materials. Energy & Fuels 9,38-44, doi:10.1021/ef00049a006 (1995).3 Pang, L. S. K., Wilson, M. A., Pallasser, R. & Prochazka, L. Isotope effects in plasma arcing experiments withvarious carbon anodes. Energy & Fuels 9, 704-706, doi:10.1021/ef00052a019 (1995).4 Wilson, M. A. et al. Fullerene production in alternative atmospheres. Carbon 31, 393-396, doi:10.1016/0008-6223(93)90045-c (1993).5 Weigle, J. C. et al. Generation of aluminum nanoparticles using an atmospheric pressure plasma torch. Journalof Physical Chemistry B 108, 18601-18607, doi:10.1021/jp049410q (2004).6 Fievet, F., Lagier, J. P., Blin, B., Beaudoin, B. & Figlarz, M. Homogeneous and heterogeneous nucleations inthe polyol process for the preparation of micron and sub-micron size metal particles. Solid State Ionics 32-3,198-205, doi:10.1016/0167-2738(89)90222-1 (1989).7 Stephan, O. et al. Doping graphitic and carbon nanotube structures with boron and nitrogen. Science 266,1683-1685, doi:10.1126/science.266.5191.1683 (1994).8 Pang, G. S. et al. Preparation of La(1-x)SrxMnO(3) nanoparticles by sonication-assisted coprecipitation.Materials Research Bulletin 38, 11-16, doi:Pii s0025-5408(02)01002-410.1016/s0025-5408(02)01002-4 (2003).9 Roucoux, A., Schulz, J. & Patin, H. Reduced transition metal colloids: A novel family of reusable catalysts?Chemical Reviews 102, 3757-3778, doi:10.1021/cr010350j (2002).10 Gui, Z. et al. Synthesis and characterization of reduced transition metal oxides and nanophase metals withhydrazine in aqueous solution. Materials Research Bulletin 38, 169-176, doi:Pii s0025-5408(02)00983-210.1016/s0025-5408(02)00983-2 (2003).厦门大学博硕士论文摘要库Degree papers are in the “Xiamen University Electronic Theses and Dissertations Database”. Fulltexts are available in the following ways: 1. If your library is a CALIS member libraries, please log on http://etd.calis.edu.cn/ and submitrequests online, or consult the interlibrary loan department in your library. 2. For users of non-CALIS member libraries, please mail to etd@xmu.edu.cn for delivery details.厦门大学博硕士论文摘要库

Investigation of Growth Mechanism of Nanocrystals and Fabrication and Application of Bionanocomposite Materials

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Investigation of Growth Mechanism of Nanocrystals and Fabrication and Application of Bionanocomposite Materials

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