【摘 要】
:
Within the last years a rapid increase of applications of Raman spectroscopy in particular to address biomedical questions has been observed.New concepts of can
【机 构】
:
InstitutfürPhysikalischeChemieundAbbeCenterofPhotonics,Friedrich-Schiller-Universit(a)tJena;Institut
论文部分内容阅读
Within the last years a rapid increase of applications of Raman spectroscopy in particular to address biomedical questions has been observed.New concepts of cancer diagnostics towards a rapid identification of sepsis pathogens were among the most important questions, which were answered by innovative Raman approaches.
其他文献
表面增强拉曼散射(SERS)光谱所具有的高灵敏度使其在化学和生物传感领域极具潜力. 理解和发展SERS光谱技术且使其成为一项分析技术,有赖于高稳定和高重复性基底的制备.1,2本
催化材料的合成,催化反应往往涉及水、溶剂、不同气氛以及高温高压等因素,并且催化剂的活性中心浓度往往极低,因此,催化材料、催化过程的动态表征及催化材料合成机理研究长期
在细胞内等复杂环境中的光学成像研究一直追求能够实现低于衍射极限的超高空间分辨率.近年来,基于单个荧光分子的光物理特性,研究者已经能够选择性地激发或压制单个荧光分子,
Visualizing individual molecules with chemical recognition is a longstanding target in catalysis, bio-science, and molecular nanotechnology.Molecular vibrations
无机非金属材料,包括氧化物、卤化物、硅酸盐、铝硅酸盐、硼酸盐、磷酸盐和铝氟酸盐等,涵盖晶体、玻璃、熔体和纳米材料等多种结构形态,在科学技术和工业等领域有着极其重要
The phase transformation of carbon materials under high pressure have attracted growing research interest due to the appearance of nanometer scale size effect a
单一介电环境中金属纳米粒子的LSPR光学性能研究己较为成熟.近年来的研究表明,当粒子处在特定的界面时,其LSPR光学特性会发生十分显著的改变.本文利用三维有限时域差分法(3D-
The field of surface-enhanced Raman spectroscopy (SERS) was initiated in 1973[1, 2].In the past four decades SERS has gone through a tortuous pathway to develop
表面等离子体(SPs)可以在微纳尺度与光发生相互作用,因其对折射率等环境刺激的高灵敏响应而被广泛地应用于基础生命科学、制药、食品卫生及环境监测等领域.尽管人们已经发展
In this talk, I will present, with some examples, our recent studies on the development of novel fluorescence sensing films and the relevant instrument creation