Most attention has been paid to quantum dots (QDs).
其中研究最多的是半导体量子点。
It has conductive effects to find the cancerous parts with quantum dots (QDs) target orientation.
利用量子点目标定位癌细胞,对于寻找癌变部位具有指导的作用。
The second part involves voltage controlled slow light effects in asymmetry double quantum dots (QDs).
第二部分是在非对称的双量子点中电压调控的慢光效应。
It is shown boron atoms exert a great influence on the size, the uniformity and the density of Ge QDs.
原子力显微镜的观察表明,硼原子不仅对量子点的大小,而且对其尺寸均匀性及密度都有很大影响。
We also discuss recent advances in using QDs in assaying of medicine and the perspective of QDs in future...
简述量子点的特性、制备方法以及近几年来在生物医学、医药领域的应用,并对其发展前景进行了展望。
The optical properties of the CdTe QDs were characterized by UV-visible Spectroscopy and Fluorescent Spectroscopy.
通过紫外-可见吸收光谱和荧光光谱对其发光特性进行了系统表征和研究。
The properties of QDs and recent developments in QDs synthesis, bioconjugation as well as their applications are discussed.
本文阐述了量子点的特性、在合成及生物结合方面的最新进展以及量子点在生物医药学中的应用。
As a new type of fluorescence materials, semiconductor quantum dots (QDs) have many advantages over the traditional materials.
半导体量子点作为一种最新型的荧光材料,与传统的荧光材料相比具有多种优势。
The two main methods of the connection between QDs and biological molecules are covalent coupling and electrostatic adsorption.
量子点与生物大分子的连接方式主要有共价耦联结合和静电吸附作用两种。
Semiconductor quantum dots (QDs) were provided with more superior performance compared with conventional organic fluorescent dyes.
量子点具有比传统的有机荧光染料更为优越的性能。
The emission wavelength of QDs was controlled by the size of the core and each single-color of QDs has narrow symmetrical emission peak.
量子点的发射波长取决于核心粒子的大小,而每一种单色量子点的发射波长窄而对称。
CONCLUSION Using the QDs nanoprobes to find the interaction between the active components of Chinese traditional medicine and cells is possible.
结论应用量子点纳米荧光探针直观发现中药有效成分与细胞之间的作用是可行的。
When the excited carrier intensity goes up, isolated QDs are correlated as a quasi-unite by the WL, screening the difference of QD sizes more or less.
随着载流子浓度的增加,可以看到各分立量子点的分立能级过渡到了各量子点相互统一的准连续态,逐渐消除了量子点的尺寸分布效应。
This thesis mainly focuses on the application of QDs in biology, especially in the cell labeling and immunoassay. The main results are as the following:1.
本论文主要工作是量子点在生物学研究中的应用,特别是在细胞标记及抗原抗体免疫反应等方面的生物应用。
Quantum dots (QDs), also known as semiconductor nanocrystals, have drawn significant attention for their potential as fluorescent probes in biological field.
量子点,又叫做无机纳米晶,由于其作为荧光探针在生物领域中的巨大应用前景,已引起生物学家们的广泛关注。
Quantum dots (QDs) have great electrical, optical properties and wide potential applications on nano-electronics, opto-electronics and quantum calculation in future.
量子点具有优异的电学和光学性能,在未来的纳米电子学、光电子学和量子计算等领域具有广泛的应用前景。
This thesis mainly focused on the synthesis of high fluorescent properties of QDs, and also studied their optical properties and their application in the analysis area.
本论文的主要工作是合成出具有高荧光性能量子点,同时也研究了其光学性质及在分析领域的应用。
This article briefly discusses the recent progresses on fluorescent QDs probes and their biological labeling including their surface modification and functionalization.
该文就量子点探针的表面修饰和功能化及其标记技术的研究进展进行了阐述。
Due to strong confinement effects of electrons and holes, QDs exhibit novel physical properties leading to important applications in microelectronics and optoelectronics.
量子点中电子和空穴强的量子限制作用使其表现出一些新颖的物理性能,从而在微电子和光电子器件方面有着重要的应用价值。
Experimental results showed that the conjugation of QDs by dBSA efficiently improve the photoluminescence quantum yield, the chemical stability of QDs and stability against photobleaching;
结果表明量子点经修饰后,量子点的量子产率、抗光漂白性及稳定性得到显著提高;
Quantum dots (QDs), with zero-dimensional electronic properties, have stimulated great interest due to their important roles in fundamental physical research and for developing novel devices.
由于半导体量子点具有零维电子特性,它不仅成为基本物理研究的重要对象,也成为研制新一代量子器件的基础。
The size-tunable optical properties and high photoluminescence quantum yields have made QDs a novel and ideal optical material for light-emitting diodes, lasers, and biological fluorescent labels.
它们因具有尺寸可调的光学性质和高的荧光量子产率而成为用于制备发光二极管、激光器和生物荧光标记物的新颖理想的光学材料。
Accordingly, fiber tapers allow QDs to adhere into the cavity and further permit the control of site-selected coupling. From the luminescence spectra, QDs are modulated effectively by cavity modes.
于是,借助于光纤锥,我们将量子点粘附在锥上,实现了量子点同微芯圆环腔的位置可控的耦合。
Objective:To observe the effect of fixative, mounting medium, temperature and sterilized method to three waves quantum dots(QDs)served as a mark on the peritoneal macrophages and normal skin of mice.
结论:不同波长量子点标记小鼠腹腔巨噬细胞和皮肤组织的效能受固定剂、封片剂、温度和除灭菌方式的影响。
Objective:To observe the effect of fixative, mounting medium, temperature and sterilized method to three waves quantum dots(QDs)served as a mark on the peritoneal macrophages and normal skin of mice.
结论:不同波长量子点标记小鼠腹腔巨噬细胞和皮肤组织的效能受固定剂、封片剂、温度和除灭菌方式的影响。
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