absorption wavemeter

简明释义

吸收式波长计

英英释义

例句

1.Using an absorption wavemeter allows for precise determination of material properties.

使用吸收波长计可以精确确定材料的性质。

2.The absorption wavemeter is essential for analyzing the absorption spectra of different chemicals.

对于分析不同化学物质的吸收光谱，吸收波长计是必不可少的。

3.We calibrated the absorption wavemeter before conducting the experiments to ensure accurate readings.

在进行实验之前，我们对吸收波长计进行了校准，以确保读数准确。

4.In the lab, the absorption wavemeter helped us identify the specific wavelengths absorbed by the dye.

在实验室中，吸收波长计帮助我们识别染料吸收的特定波长。

5.The researcher used an absorption wavemeter to measure the spectral absorption of the sample.

研究人员使用吸收波长计来测量样品的光谱吸收。

作文

The field of optics and photonics has witnessed numerous advancements over the years, one of which is the development of the absorption wavemeter. This instrument plays a crucial role in measuring the absorption characteristics of various materials when exposed to light. By understanding how different substances absorb light at specific wavelengths, scientists can gain insights into their chemical composition, physical properties, and potential applications in various industries.An absorption wavemeter operates on the principle of measuring the intensity of light before and after it passes through a sample material. When light encounters a material, certain wavelengths are absorbed while others are transmitted or reflected. The absorption wavemeter quantifies this change in intensity, allowing researchers to calculate the absorption coefficient of the material at different wavelengths. This coefficient is essential for understanding the material's interaction with light, which is fundamental in fields such as material science, chemistry, and environmental studies.One of the significant advantages of using an absorption wavemeter is its ability to provide precise measurements across a wide range of wavelengths. This capability is particularly beneficial in applications such as spectroscopy, where detailed information about the electronic transitions and molecular vibrations of substances is required. For instance, in pharmaceuticals, the absorption wavemeter can be utilized to analyze the purity of compounds by examining their absorption spectra. Any deviations from expected absorption patterns can indicate the presence of impurities or alterations in the chemical structure.Moreover, the absorption wavemeter is instrumental in environmental monitoring. It can be used to measure the absorption of pollutants in the atmosphere or bodies of water, providing valuable data for assessing environmental health. By analyzing how specific contaminants absorb light, researchers can identify their concentrations and potential impacts on ecosystems and human health.The design of modern absorption wavemeters often incorporates advanced technologies such as lasers and photodetectors, enhancing their sensitivity and accuracy. These advancements allow for real-time monitoring and analysis, making them indispensable tools in laboratories and industrial settings. As research continues to evolve, the absorption wavemeter is likely to undergo further innovations, expanding its capabilities and applications.In conclusion, the absorption wavemeter is a vital instrument in the realm of optics, providing essential data for a variety of scientific and industrial applications. Its ability to measure the absorption of light by materials not only enhances our understanding of their properties but also aids in practical applications such as quality control, environmental monitoring, and research. As technology progresses, the absorption wavemeter will continue to play a significant role in advancing our knowledge and addressing challenges across multiple fields. Understanding the principles and applications of the absorption wavemeter is crucial for anyone involved in scientific research or industry that deals with light-matter interactions.

光学和光子学领域多年来经历了许多进步，其中之一就是开发了吸收波长计。该仪器在测量各种材料在光照射下的吸收特性方面发挥着至关重要的作用。通过了解不同物质在特定波长下如何吸收光，科学家可以深入了解它们的化学成分、物理特性及其在各个行业中的潜在应用。吸收波长计的工作原理是测量光在通过样品材料之前和之后的强度。当光遇到某种材料时，某些波长会被吸收，而其他波长则会被传输或反射。吸收波长计量化这种强度变化，使研究人员能够计算材料在不同波长下的吸收系数。这个系数对于理解材料与光的相互作用至关重要，这在材料科学、化学和环境研究等领域中都是基础。使用吸收波长计的一个显著优点是它能够在广泛的波长范围内提供精确的测量。这一能力在光谱学等应用中尤其有益，因为需要关于物质的电子跃迁和分子振动的详细信息。例如，在制药行业中，吸收波长计可用于通过分析化合物的吸收光谱来检测其纯度。任何偏离预期吸收模式的现象都可能表明存在杂质或化学结构的变化。此外，吸收波长计在环境监测中也非常重要。它可以用来测量大气或水体中污染物的吸收，为评估环境健康提供宝贵的数据。通过分析特定污染物如何吸收光，研究人员可以识别其浓度及对生态系统和人类健康的潜在影响。现代吸收波长计的设计通常结合了激光和光电探测器等先进技术，提高了其灵敏度和准确性。这些进步使得实时监测和分析成为可能，使其成为实验室和工业环境中不可或缺的工具。随着研究的不断发展，吸收波长计可能会经历进一步的创新，扩展其能力和应用。总之，吸收波长计是光学领域的重要仪器，为各种科学和工业应用提供了基本数据。它测量材料对光的吸收能力，不仅增强了我们对其特性的理解，还有助于质量控制、环境监测和研究等实际应用。随着技术的进步，吸收波长计将继续在推动我们知识的发展和解决多个领域的挑战中发挥重要作用。理解吸收波长计的原理和应用，对于任何参与科学研究或处理光-物质相互作用的行业的人来说都是至关重要的。