spectroscopical

简明释义

英[spektrəˈskɒpɪkəl]美[spektrəˈskɑːpɪkəl]

adj. 分光；分光镜的

英英释义

单词用法

同义词

反义词

例句

1.As a spectroscopical element, grating has been widely introduced into numerous areas such as spectrometer, DVD, laser, telescope, grating polarization apparatus.

光栅作为一种分光元件，广泛应用于光谱仪、DVD、激光器、望远镜、光栅偏振器等诸多领域。

2.As a spectroscopical element, grating has been widely introduced into numerous areas such as spectrometer, DVD, laser, telescope, grating polarization apparatus.

光栅作为一种分光元件，广泛应用于光谱仪、DVD、激光器、望远镜、光栅偏振器等诸多领域。

3.Using spectroscopical 光谱学的 methods, scientists can determine the age of ancient artifacts.

科学家可以使用光谱学的方法来确定古代文物的年代。

4.The researchers conducted a series of spectroscopical 光谱学的 analyses to identify the chemical composition of the new material.

研究人员进行了系列的光谱学的分析，以确定新材料的化学成分。

5.The spectroscopical 光谱学的 study revealed unexpected features in the star's light spectrum.

这项光谱学的研究揭示了星光谱中意想不到的特征。

6.The team employed spectroscopical 光谱学的 analysis to detect pollutants in water samples.

团队采用光谱学的分析来检测水样中的污染物。

7.In environmental science, spectroscopical 光谱学的 techniques are used to monitor air quality.

在环境科学中，光谱学的技术用于监测空气质量。

作文

The field of science is vast and varied, encompassing numerous disciplines that seek to understand the universe around us. One such discipline is spectroscopy, which plays a crucial role in various scientific investigations. The term spectroscopical refers to the methods and techniques used to analyze the interaction between light and matter. By studying these interactions, scientists can gain valuable insights into the composition and properties of different substances. This essay will explore the significance of spectroscopical analysis in fields such as chemistry, astronomy, and environmental science.In chemistry, spectroscopical techniques are fundamental for identifying chemical compounds and understanding their structures. For instance, infrared spectroscopy allows chemists to determine functional groups within a molecule by measuring the absorption of infrared light. Each type of bond in a molecule absorbs light at specific wavelengths, which creates a unique fingerprint that can be analyzed. This method not only aids in identifying unknown substances but also helps in monitoring reactions and studying reaction mechanisms. Without spectroscopical methods, our understanding of chemical processes would be significantly limited.Astronomy is another field where spectroscopical techniques have revolutionized our understanding of the universe. By analyzing the light emitted from stars and galaxies, astronomers can determine their composition, temperature, density, and motion. For example, the Doppler effect observed in the light spectrum of distant stars allows scientists to measure their velocity relative to Earth. This information is crucial for understanding the expansion of the universe and the behavior of celestial bodies. The ability to conduct spectroscopical studies on astronomical objects has opened up new avenues for research and discovery, enabling us to explore the cosmos in ways that were previously unimaginable.Environmental science also benefits greatly from spectroscopical techniques. Scientists use these methods to monitor pollution levels, assess the quality of water and air, and study climate change. For instance, remote sensing technologies utilize spectroscopical data to detect changes in vegetation health, soil composition, and atmospheric conditions. By analyzing the light reflected off the Earth's surface, researchers can gather essential information about ecological systems and human impact on the environment. This application of spectroscopical methods is vital for developing strategies to combat environmental issues and promote sustainability.In conclusion, the term spectroscopical encompasses a range of techniques that are indispensable across various scientific disciplines. From chemistry to astronomy and environmental science, spectroscopical analysis provides critical insights that enhance our understanding of the natural world. As technology continues to advance, the applications of spectroscopical methods will undoubtedly expand, leading to new discoveries and innovations that will shape the future of science. The importance of spectroscopical techniques cannot be overstated, as they serve as a bridge between theory and practical application, allowing us to unlock the mysteries of the universe and improve our quality of life.

科学领域广阔而多样，涵盖了众多旨在理解我们周围宇宙的学科。其中一个学科是光谱学，它在各种科学研究中发挥着至关重要的作用。术语spectroscopical指的是用于分析光与物质之间相互作用的方法和技术。通过研究这些相互作用，科学家可以获得有关不同物质的成分和性质的宝贵见解。本文将探讨spectroscopical分析在化学、天文学和环境科学等领域的重要性。在化学中，spectroscopical技术对于识别化合物和理解其结构至关重要。例如，红外光谱法允许化学家通过测量红外光的吸收来确定分子中的功能团。分子中的每种类型的键在特定波长下吸收光，这会产生独特的指纹，可以进行分析。这种方法不仅有助于识别未知物质，还帮助监测反应和研究反应机制。如果没有spectroscopical方法，我们对化学过程的理解将大大受限。天文学是另一个因spectroscopical技术而彻底改变我们对宇宙理解的领域。通过分析从恒星和星系发出的光，天文学家可以确定它们的成分、温度、密度和运动。例如，远处恒星光谱中观察到的多普勒效应使科学家能够测量它们相对于地球的速度。这些信息对于理解宇宙的扩展和天体的行为至关重要。对天文学对象进行spectroscopical研究的能力为研究和发现开辟了新途径，使我们能够以前所未有的方式探索宇宙。环境科学也大大受益于spectroscopical技术。科学家使用这些方法监测污染水平、评估水和空气的质量以及研究气候变化。例如，遥感技术利用spectroscopical数据检测植被健康、土壤成分和大气条件的变化。通过分析从地球表面反射的光，研究人员可以收集有关生态系统和人类对环境影响的重要信息。这种spectroscopical方法的应用对于制定应对环境问题和促进可持续发展的战略至关重要。总之，术语spectroscopical涵盖了一系列在各个科学学科中不可或缺的技术。从化学到天文学，再到环境科学，spectroscopical分析提供了增强我们对自然世界理解的关键见解。随着技术的不断进步，spectroscopical方法的应用无疑将扩展，导致新的发现和创新，这将塑造科学的未来。spectroscopical技术的重要性不容小觑，因为它们充当理论与实践应用之间的桥梁，使我们能够揭开宇宙的奥秘，改善我们的生活质量。