fluorimetric

简明释义

英[ˌflʊə.rɪˈmɛ.trɪk]美[ˌflʊə.rɪˈmɛ.trɪk]

adj. 荧光的

英英释义

单词用法

同义词

反义词

例句

1.In this paper, the synthesis and fluorimetric properties of 8-aminoquinoline derivatives and their applications in fluorimetric analysis are summarized. 46 references are cited.

本文综述了8 -氨基喹啉类试剂的合成，荧光性能及其在荧光分析中的应用研究进展。参考文献46篇。

2.In this paper, the synthesis and fluorimetric properties of 8-aminoquinoline derivatives and their applications in fluorimetric analysis are summarized. 46 references are cited.

本文综述了8 -氨基喹啉类试剂的合成，荧光性能及其在荧光分析中的应用研究进展。参考文献46篇。

3.A simple and sensitive fluorimetric method has been developed for the determination of trace palladium with N-(1-naphthyl)ethylene diamine(NPED) as a fluorescence reagent.

研究了市售荧光试剂N-1-萘基乙二胺（NPED）作为荧光探针测定钯的新方法。

4.Results There is no obvious difference on quality between the Russian natural bezoar and Chinese natural bezoar, but two characteristic fluorimetric dots can be detected.

结果俄罗斯产天然牛黄和国产天然牛黄质量无明显区别，分析中出现了两个特征荧光斑点。

5.In this paper, the synthesis and fluorimetric properties of 8-aminoquinoline derivatives and their applications in fluorimetric analysis are summarized.

本文综述了8 -氨基喹啉类试剂的合成，荧光性能及其在荧光分析中的应用研究进展。

6.A measurement of fluorimetric intensity by using two fluorimetric reference solutions to check the instrument is described.

本文叙述使用两个荧光参比溶液调节仪器的荧光强度测量法。

7.Objective To optimize the the NADPgenerating fluorimetric method for aldose reductase (AR) activity.

目的找出优化NADP生成荧光法测定红细胞醛糖还原酶(AR)活性的方案。

8.The optimum selective rules of fluorimetric reference solutions are also discussed.

讨论了荧光参比溶液的最佳选择原则。

9.The mechanism of fluorimetric reaction has been discussed.

并对反应机理作了初步探讨。

10.The laboratory employed fluorimetric methods to detect trace levels of pollutants in water samples.

实验室采用荧光测定方法检测水样中污染物的微量。

11.Researchers developed a new fluorimetric assay for measuring the concentration of proteins in biological samples.

研究人员开发了一种新的荧光测定方法，用于测量生物样本中蛋白质的浓度。

12.Using fluorimetric analysis, scientists were able to monitor the degradation of pharmaceuticals in the environment.

通过使用荧光测定分析，科学家能够监测环境中药物的降解情况。

13.The fluorimetric technique is widely used in clinical laboratories for diagnosing various diseases.

在临床实验室中，荧光测定技术被广泛用于诊断各种疾病。

14.A fluorimetric method was developed to quantify the levels of heavy metals in soil.

开发了一种荧光测定方法来量化土壤中重金属的含量。

作文

Fluorimetry is a powerful analytical technique used to measure the concentration of fluorescent compounds in various samples. One of the most important aspects of this technique is its *fluorimetric* 荧光测定 properties, which allow for highly sensitive detection of substances that may be present in very low concentrations. The basic principle of *fluorimetric* 荧光测定 analysis involves the excitation of a sample with a specific wavelength of light, causing certain molecules within the sample to emit light at a different wavelength. This emitted light can then be measured and quantified, providing valuable information about the sample's composition. The applications of *fluorimetric* 荧光测定 techniques are vast and varied. In environmental science, for instance, researchers utilize *fluorimetric* 荧光测定 methods to detect pollutants in water bodies. By measuring the fluorescence of certain contaminants, scientists can assess the level of pollution and its potential impact on aquatic life. Similarly, in the field of biochemistry, *fluorimetric* 荧光测定 is employed to study the interactions between proteins and other molecules, allowing researchers to gain insights into complex biological processes. One of the key advantages of *fluorimetric* 荧光测定 techniques is their high sensitivity and specificity. Unlike other analytical methods that may require large sample sizes or extensive sample preparation, *fluorimetric* 荧光测定 can often analyze small volumes of samples with minimal interference from other substances. This makes it an ideal choice for applications in clinical diagnostics, where detecting low levels of biomarkers can be crucial for early disease diagnosis. Moreover, advancements in technology have significantly improved the capabilities of *fluorimetric* 荧光测定 instruments. Modern fluorimeters are equipped with sophisticated software that allows for real-time data analysis and interpretation. This not only enhances the efficiency of the analysis but also increases the accuracy of the results. As a result, *fluorimetric* 荧光测定 has become a standard method in many laboratories around the world. However, despite its numerous advantages, there are some limitations to *fluorimetric* 荧光测定. For instance, the presence of background fluorescence from other components in a sample can sometimes interfere with the measurements, leading to inaccurate results. To mitigate this issue, researchers must carefully design their experiments and choose appropriate wavelengths for both excitation and emission. Additionally, not all substances exhibit fluorescence, which can limit the applicability of *fluorimetric* 荧光测定 for certain analyses. In conclusion, *fluorimetric* 荧光测定 is a vital analytical technique that plays a crucial role in various scientific fields. Its ability to provide sensitive and specific measurements makes it indispensable for researchers and professionals alike. As technology continues to evolve, we can expect further advancements in *fluorimetric* 荧光测定 methods, leading to even more innovative applications and discoveries in the future. Understanding the principles and applications of *fluorimetric* 荧光测定 is essential for anyone looking to delve into the world of analytical chemistry and its practical uses.

荧光测定是一种强大的分析技术，用于测量各种样品中荧光化合物的浓度。该技术最重要的方面之一是其*荧光测定* 荧光测定 特性，它允许对可能存在于非常低浓度中的物质进行高度灵敏的检测。*荧光测定* 荧光测定 分析的基本原理涉及用特定波长的光激发样品，导致样品中的某些分子以不同波长发出光。这种发出的光可以被测量和量化，从而提供有关样品成分的宝贵信息。 *荧光测定* 荧光测定 技术的应用广泛而多样。例如，在环境科学中，研究人员利用*荧光测定* 荧光测定 方法检测水体中的污染物。通过测量某些污染物的荧光，科学家可以评估污染水平及其对水生生物的潜在影响。同样，在生物化学领域，*荧光测定* 荧光测定 被用于研究蛋白质与其他分子之间的相互作用，使研究人员能够深入了解复杂的生物过程。 *荧光测定* 荧光测定 技术的一个关键优势是其高灵敏度和特异性。与其他分析方法可能需要较大样本量或大量样品准备不同，*荧光测定* 荧光测定 通常可以分析小体积样品，且干扰最小。这使其成为临床诊断中理想的选择，在那里检测低水平生物标志物对于早期疾病诊断至关重要。 此外，技术的进步显著提高了*荧光测定* 荧光测定 仪器的能力。现代荧光仪配备了先进的软件，可以实时分析和解释数据。这不仅提高了分析的效率，还增加了结果的准确性。因此，*荧光测定* 荧光测定 已成为世界各地许多实验室的标准方法。 然而，尽管有许多优点，*荧光测定* 荧光测定 也存在一些局限性。例如，样品中其他成分的背景荧光有时会干扰测量，导致不准确的结果。为了减轻这个问题，研究人员必须仔细设计实验，并选择适当的激发和发射波长。此外，并非所有物质都表现出荧光，这可能限制*荧光测定* 荧光测定 在某些分析中的适用性。 总之，*荧光测定* 荧光测定 是一种重要的分析技术，在各个科学领域中发挥着至关重要的作用。其提供灵敏和特异性测量的能力使其对研究人员和专业人士而言不可或缺。随着技术的不断发展，我们可以期待*荧光测定* 荧光测定 方法的进一步进步，带来更多创新的应用和未来的发现。理解*荧光测定* 荧光测定 的原理和应用对任何希望深入了解分析化学及其实际用途的人来说都是至关重要的。