机械抛光铜金属表面对罗丹明的荧光增强效应

应用激光光谱学方法,研究了铜表面Rh6G分子的荧光增强效应对于金属衬底表面所形成的氧化层的依赖关系,探索了由于空气氧化而形成的氧化层在表面荧光增强效应中的重要意义和作用机理.实验采用罗丹明6G荧光探针分子,在532nm连续光激发下,研究机械抛光铜金属衬底在经历不同氧化时间,对吸附其表面的Rh6G分子的荧光增强效果.研究结果表明,适当控制金属样品表面的氧化时间,金属铜表面对若丹明分子的荧光发射表现出猝灭和增强效应.金属氧化层起到了隔离荧光分子与金属表面的作用,减弱了由于激发态荧光分子向金属转移非辐射能量和在金属表面诱导反向偶极子而产生的荧光猝灭效应,从而提高了纯金属铜表面荧光增强辐射行为.因此在微纳金属衬底的荧光增强效应研究中,采用适当的实验手段,精确控制隔离层间距,是表面增强光谱获取的重要途径之一.     

有机分子隔离层对机械抛光金属银表面的罗丹明6G荧光增强效应的影响

采用物理吸附法,在机械抛光纯银表面引入对巯基苯胺(p-Amiothiophenol,PATP)分子充当隔离层,运用激光光谱学方法研究隔离层对位于银表面附近的罗丹明6G(Rh6G)分子的荧光增强效应影响。实验结果表明,未经PATP分子修饰的机械抛光金属衬底对Rh6G分子表现为猝灭效应,而经过PATP分子修饰后的银表面对Rh6G分子的荧光发射具有增强效应。根据局域表面等离子共振及辐射能量转移模型对实验观测所得结果进行了分析研究,结果表明,PATP有机分子隔离层的引入有效地减小了荧光分子与金属衬底之间的无辐射能量速率,提高了荧光辐射强度。     

纳米银粒子表面吸附染料分子的荧光增强及荧光猝灭现象

本文通过阴、阳离子型染料分子荧光素钠(FS)及若丹明6G(Rh6G)吸附在银胶体系内纳米银颗粒表面上,首次发现了FS的荧光增强谱及Rh6G的荧光猝灭谱.引起荧光增强及荧光猝灭的因素,除局域场和分子到金属表面能量转移这两个方面外,还与纳米银表面与被吸附分子之间的距离有关.     

罗丹明6G在银纳米线阵列上的SERS光谱研究

制备出有序、均匀的活性衬底一直足表面增强拉曼散射(SERS)研究中的关键.阳极氧化法制备的多孔氧化铝膜的结构有序、均匀,为纳米金属SERS基底的制备提供了模板.以沉积了银的多孔氧化铝组装体为衬底,研究了罗丹明6G(Rh6G)分子的表面增强拉曼散射光谱.结果表明,沉积了银的多孔氧化铝模板是很好的SERS衬底,Rh6G分子在此衬底上的SERS谱强度与银纳米线在表面的显露高度有关,而其拉曼频移未受表面状态的影响,而PO43-离子的存在使SERS强度得到很大提高.     

表面荧光机制的理论研究

本文研究了 Rh B分子的 539.0 nm和 572 .5nm两荧光峰在表面增强活性银胶颗粒表面上的增强和淬灭效应 :在同一分子体系中同时观察到 530 .0 nm荧光峰的增强和 572 .5nm荧光峰的淬灭 ,并对其进行了理论计算。结果表明这两个荧光峰的增强或淬灭主要取决于局域电磁场增强和分子到金属表面无辐射能量转移衰减过程的竞争效应。当满足吸收共振增强和辐射共振增强时 ,荧光被增强 ;反之 ,荧光被淬灭。计算表明 ,荧光增强因子最高为 1     

银纳米粒子与R6G分子间的电荷转移

本文通过吸收光谱、表面增强垃曼光谱、荧光光谱等手段研究了银纳米粒子与罗丹明6G（R6G）分子之间的相互作用,结果表明：银纳米粒子表面与R6G分子之间存在电荷转移效应。表现为吸收谱长波方向出现银粒子－R6G复合体的吸收带,R6G分子的拉曼振动模得到显著增强,而其荧光得到明显猝灭;AgN特征拉曼振动带的出现服银米粒子与R6G分子是通过银粒表面的活位与R6G分子中的氮原子配位形成复合体而发生电荷转移的。     

纳米银胶中PVP和Alq3的荧光猝灭研究

本文通过湿法化学还原法合成了平均粒径为4.42nm、标准差为0.98nm的球形银纳米颗粒,并研究了在不同反应时间后获得的银纳米颗粒对PVP和Alq3的荧光猝灭效应。通过深入研究发现,PVP的荧光猝灭效应主要由于其分子链上的酮基与Ag颗粒之间发生了静电吸附,进而导致处在激发态的PVP分子与银颗粒之间产生电子或者能量转移(即非辐射弛豫),猝灭了PVP的荧光发光;而Alq3的荧光猝灭效应则主要归因于银纳米颗粒的欧姆损耗。通过采用时域有限差分法进行模拟发现,溶液中随机分布的银纳米颗粒,不仅能够吸收激发电磁波,削弱激发场强度,而且能够吸收荧光分子辐射的电磁波,进而猝灭了Alq3分子的荧光效应。这些研究成果将有利于了解金属纳米颗粒与PVP及Alq3分子荧光发光之间的关系,为调控荧光发光提供指导。     

氧化石墨烯猝灭罗丹明6G荧光的机理研究（英文）

本文采用稳态与瞬态荧光测量技术,研究了一系列具有不同C/O比率的氧化石墨烯(GO)纳米片猝灭罗丹明6G(R6G)荧光的行为机制.发现GO纳米片上的羰基官能团在R6G的荧光猝灭过程中起主导作用,其静态猝灭机制可用"作用球"模型来描述,并且GO与R6G所形成的基态复合物也是导致R6G荧光静态猝灭的原因之一.本工作为R6G/GO体系的荧光猝灭机理提供了有益的解读.     

染料分子吸附在正、负电性纳米银上的荧光增强及荧光猝灭现象

制备了两种不同表面电性的胶态纳米银 ,选取阴离子型染料分子荧光素钠、既有阴离子基团又有阳离子的染料分子罗丹明B ,研究其在两种纳米银表面的荧光增强及荧光猝灭现象 .当罗丹明B(RhB)分子分别吸附在这两种纳米银上时 ,对负电性纳米银 ,观察到荧光猝灭、荧光峰红移现象 ,且在分子的浓度适当时 ,加入KBr可获得较强的表面增强拉曼光谱 ;在正电性纳米银上 ,当分子的浓度较大时观察到荧光猝灭 ,当分子的浓度较小时观察到荧光增强 .而当荧光素钠分子 (FS)分别吸附在这两种纳米银上时 ,在负电性纳米银 ,观察到荧光猝灭 ;在正电性纳米银上观察荧光急剧增强现象 .从分子的结构及纳米银表面局域场增强或无辐射通道的增加对增强和猝灭的原因作了讨论 .     

氧化石墨烯如何猝灭罗丹明6G的荧光

考察了水相溶液中氧化石墨烯对罗丹明6G的高效荧光猝灭．借助稳态及时间分辨荧光光谱测量,结合对该二元体系线性吸收谱变化的细致分析,澄清了相关荧光猝灭机理,即动态猝灭与静态猝灭的联合猝灭机制．提出在静态猝灭过程中罗丹明6G与氧化石墨烯所形成的可能的基态复合物,并进一步讨论了二者之间的光致电子转移过程．     

氧化钛薄膜调控金属铜的表面等离子体共振特性研究

提出了一种利用氧化钛薄膜对金属铜薄膜表面等离子体共振特性调制的想法。实验中首先使用电子束蒸发制备一批同等厚度的氧化钛薄膜,再利用磁控溅射方法在氧化钛薄膜上沉积厚度为5～80 nm不等的金属铜薄膜。测试结果表明,氧化钛膜层对不同厚度的金属铜薄膜表面等离子体共振增强具有不同调制效果,金属铜薄膜厚度小于20 nm时,底层的氧化钛薄膜对Cu薄膜表面等离子体共振增强效果显著,且随着金属Cu膜层厚度增加表面等离子体共振峰发生蓝移,而当金属铜膜层的厚度超过20 nm时,共振增强效果因金属Cu薄膜消光能力的上升而开始减弱。     

Influence of surface orientation and defects on early-stage oxidation and ultrathin oxide growth on pure copper

We investigate oxidation and oxide growth on single-crystal copper surfaces using reactive molecular dynamics simulation. The kinetics of surface oxide growth are strongly correlated with the microstructure of the metal substrates. Simulating oxide layer growth along the (100), (110), and (111) orientations of crystalline copper, oxidation characteristics are investigated at temperatures of 300?K and 600?K. The oxidation kinetics are found to strongly depend on the surface orientation, ambient temperature, and surface defects. The effect of surface morphology on oxidation characteristics is analyzed by comparing oxygen adsorption on various sites and the structure factor. The surface oxide formed on (100) retains the initial crystal structure in the 300–600?K range. The (100) surface shows the highest oxidation rate at both temperature conditions but saturates, facilitating oxygen adsorption on hollow sites. The oxidation kinetics of the (100) orientation are found to be not significantly affected by surface defects. (110) shows modest oxidation at 300?K but the highest oxidation is observed at 600?K. By surface disorder and reconstruction, the oxide layer is produced continuously. The (111) surface is sensitive to ambient temperature and surface defects, showing that surface reconstruction is a key element for further oxidation. The charge distribution of oxidized Cu atoms indicates multiple groups of stoichiometric oxides, while the fraction of CuO-like characteristics increases significantly on the (110) and (111) orientations at higher temperature (600?K). The energetics and mechanisms of oxidation on Cu metal substrates at the nanoscale are discussed in detail, and comparisons with available experimental and other theoretical studies are presented wherever possible.     

STM tip-enhanced photoluminescence from porphyrin film

Tunneling electrons-induced molecular fluorescence in organic film is enhanced by the surface plasmons. The plasmon enhancement can be expected not only by the plasmons of the substrate but also by the noble metal tip of scanning tunneling microscope (STM). In this report we investigate the tip effect in photoluminescence of meso-tetrakis(3,5-di-tertiarybutyl-phenyl)porphyrin (H₂TBPP) film on indium tin oxide (ITO) combined with a STM. The experimental result shows the PL of molecules is enhanced by an Ag tip. This enhancement factor is evaluated larger than 2000.     

Molecular engineered silica surfaces with an assembled anthracene monolayer as a fluorescent sensor for organic copper(II) salts

A novel fluorescence film has been fabricated by covalently coupling anthracene on a glass plate surface via a long flexible “Y” type spacer. Fluorescence measurement demonstrated that the emission of the film is dominated by anthracene monomer emission, and the emission can be selectively quenched by organic copper(II) salts including copper acetate, copper citrate, copper tartrate, etc. Addition of inorganic copper(II) salts like Cu(NO₃)₂, CuSO₄, CuCl₂, etc., however, has little effect upon the emission of the film. This observation was explained by considering the screening effect of the spacer layer, or spacer clusters, or even spacers adopting compact coiled conformation. Different from the reported fluorescence films with similar structures, immobilization of anthracene via a “Y” type spacer on a glass plate surface makes the fluorophore moieties exist in two different states, that is some of them were embedded within the spacer structures, and some of them might stay out of the structures. This hypothesis has been confirmed by model system, solvent effect and quenching mechanism studies. The emission of the film is sensitive to the presence of organic copper(II) salts like copper acetate. The response of the film to copper acetate is fully reversible. Presence of other inorganic salts, including Pb(Ac)₂, Cd(Ac)₂, Zn(Ac)₂, and inorganic copper(II) salts has little effect upon the sensing performance of the film to copper acetate.     

Investigation of oxidation inhibition properties of vaporized self-assembled multilayers on copper nanopowders

Stability against oxidation was investigated for vaporized self-assembled multilayers on nano-sized Cu powders. 100 nm-sized copper powders were coated with 1-octanethiol to make a passivation layer against oxidation.As a result, the surface resistivity of the coated and uncoated nano-sized copper powders differed by two orders of magnitude. XPS analysis was used to monitor changes in the amount of sulfur and oxygen on the surface of octanethiol-coated Cu nano powders over a period of time. While sulfur was detected for up to 75 days, the amount of oxygen increased dramatically after 35 days, indicating sign of partial oxidation. Furthermore, HR-TEM images showed that the octanethiol film was consistently 10 nm thick, for up to 35 days. After 35 days exposure to the air, the octanethiol film was partially damaged and its diffraction pattern detected the presence of Cu₂O. Based on these findings, vaporized octanethiol coating protected the copper nano powders from oxidation for up to 35 days. Therefore this oxidation inhibition property of VSAMs coating method on Cu powders achieves a great milestone toward inkjet printing technology.     

金属Sn薄膜的高温氧化与表面特征

侧重研究了高温氧化（300－550℃）引起金属Sn薄膜的表面显微形貌和表面氧化状态的变化．利用原子力显微镜（AFM）的测量，观察到金属Sn薄膜表面的金属晶粒呈现近似方形的显微形貌，但是金属Sn氧化薄膜表面的金属氧化物颗粒却具有近似圆形的显微形貌，因此，金属晶粒的高温氧化是一个各向异性的过程．在X射线光电子能谱（XPS）测量的基础上，不仅发现在金属Sn薄膜和金属Sn氧化薄膜的表面都存在大量的吸附氧粒子，而且发现吸附氧粒子的吸附形式与表面的氧化程度有关 关键词：     

Synchrotron PEEM and ToF‐SIMS study of oxidized heterogeneous pentlandite,pyrrhotite and chalcopyrite

Synchrotron‐based photoemission electron microscopy (PEEM; probing the surface region) and time‐of‐flight secondary ion mass spectrometry (ToF‐SIMS; probing the uppermost surface layer) have been used to image naturally heterogeneous samples containing chalcopyrite (CuFeS₂), pentlandite [(Ni,Fe)₉S₈] and monoclinic pyrrhotite (Fe₇S₈) both freshly polished and exposed to pH 9 KOH for 30 min. PEEM images constructed from the metal L₃ absorption edges were acquired for the freshly prepared and solution‐exposed mineral samples. These images were also used to produce near‐edge X‐ray absorption fine‐structure spectra from regions of the images, allowing the chemistry of the surface of each mineral to be interrogated, and the effect of solution exposure on the mineral surface chemistry to be determined. The PEEM results indicate that the iron in the monoclinic pyrrhotite oxidized preferentially and extensively, while the iron in the chalcopyrite and pentlandite underwent only mild oxidation. The ToF‐SIMS data gave a clearer picture of the changes happening in the uppermost surface layer, with oxidation products being observed on all three minerals, and significant polysulfide formation and copper activation being detected for pyrrhotite.     

Self-assembled synthesis of SEF-active silver dendrites by galvanic displacement on copper substrate

In this paper, an effective substrate for surface-enhanced fluorescence, which consists of dendritic silver nanostructure on copper surface, was fabricated by modified galvanic displacement reaction at room temperature. It was found that the fluorescence efficiency of Rh6G probe molecules on the substrate depended on the period of the nanostructure growth. And it increased with the enrichment of fine-branches of the dendritic silver nanostructure. The experimental results indicated that the fine nanostructure with dendritic distribution can produce better fluorescence enhancement with the help of proper control over the reaction condition. It is important for studying the mechanism and the potential applications of enhanced fluorescence effect.