achromatic magnetic mass spectrometer

简明释义

1. 消色差磁性质谱仪; 2. 消色差磁质谱计;

英英释义

例句

1.The achromatic magnetic mass spectrometer provides high-resolution data crucial for understanding complex mixtures.

该无色差磁质谱仪提供的高分辨率数据对于理解复杂混合物至关重要。

2.The research team utilized an achromatic magnetic mass spectrometer to analyze the isotopic composition of the samples.

研究小组利用无色差磁质谱仪分析样品的同位素组成。

3.In environmental studies, an achromatic magnetic mass spectrometer can help detect trace pollutants in water sources.

在环境研究中，无色差磁质谱仪可以帮助检测水源中的微量污染物。

4.The accuracy of the achromatic magnetic mass spectrometer makes it ideal for pharmaceutical applications.

由于其高精度，无色差磁质谱仪非常适合制药应用。

5.Using an achromatic magnetic mass spectrometer, scientists were able to identify new compounds in the sample.

科学家们使用无色差磁质谱仪成功识别了样品中的新化合物。

作文

The field of analytical chemistry has witnessed significant advancements over the past few decades, particularly in the development of sophisticated instruments designed to analyze the composition of various substances. One such instrument that has gained prominence is the achromatic magnetic mass spectrometer. This device plays a crucial role in identifying and quantifying chemical compounds with high precision and accuracy.To understand the significance of the achromatic magnetic mass spectrometer, it is essential to break down its components. The term 'achromatic' refers to the ability of the instrument to minimize chromatic aberration, which can occur when different wavelengths of light are focused at different points. In mass spectrometry, this characteristic allows for clearer separation of ions based on their mass-to-charge ratio, leading to more accurate results.The 'magnetic' aspect of the achromatic magnetic mass spectrometer indicates that it utilizes magnetic fields to manipulate charged particles. By applying a magnetic field, the instrument can effectively separate ions according to their mass. This method is particularly advantageous because it enhances the resolution of the mass spectrometer, enabling it to distinguish between ions that are very similar in mass.Mass spectrometry itself is a powerful analytical technique used across various scientific disciplines, including chemistry, biology, and environmental science. It involves ionizing chemical species and sorting the ions based on their mass-to-charge ratios. The achromatic magnetic mass spectrometer takes this process a step further by ensuring that the data collected is not only precise but also reliable.One of the primary applications of the achromatic magnetic mass spectrometer is in the field of pharmaceuticals, where it is used to analyze drug compositions and detect impurities. This capability is vital for ensuring the safety and efficacy of medications before they reach the market. Additionally, researchers utilize this technology to study metabolic processes in living organisms, providing insights into how different substances interact within biological systems.Moreover, environmental scientists employ the achromatic magnetic mass spectrometer to monitor pollutants in air, water, and soil. By accurately identifying and quantifying harmful substances, this instrument contributes significantly to environmental protection efforts. Its ability to deliver rapid results makes it an invaluable tool for both regulatory agencies and research institutions.In conclusion, the achromatic magnetic mass spectrometer represents a remarkable achievement in the realm of analytical instrumentation. Its unique design and functionality enable scientists to conduct detailed analyses with unprecedented accuracy. As technology continues to evolve, we can expect further improvements in mass spectrometry techniques, paving the way for new discoveries across various scientific fields. The ongoing development of the achromatic magnetic mass spectrometer will undoubtedly enhance our understanding of complex chemical interactions and contribute to advancements in health, safety, and environmental sustainability.

分析化学领域在过去几十年中经历了显著的进步，特别是在开发旨在分析各种物质成分的复杂仪器方面。其中一种日益受到关注的仪器是无色差磁质谱仪。该设备在识别和定量化学化合物方面发挥着至关重要的作用，具有高精度和准确性。要理解无色差磁质谱仪的重要性，有必要拆解其组成部分。“无色差”一词指的是仪器能够最小化色差，这种色差会在不同波长的光聚焦于不同点时发生。在质谱分析中，这一特性允许根据离子的质量电荷比进行更清晰的离子分离，从而导致更准确的结果。“磁性”这一方面表明无色差磁质谱仪利用磁场来操控带电粒子。通过施加磁场，仪器可以有效地根据质量分离离子。这种方法尤其有利，因为它提高了质谱仪的分辨率，使其能够区分质量非常相似的离子。质谱法本身是一种强大的分析技术，广泛应用于化学、生物学和环境科学等多个科学领域。它涉及对化学物质进行电离，并根据其质量电荷比对离子进行排序。无色差磁质谱仪进一步提升了这一过程，确保所收集的数据不仅精确，而且可靠。无色差磁质谱仪的主要应用之一是在制药领域，用于分析药物成分和检测杂质。这一能力对于确保药物在进入市场前的安全性和有效性至关重要。此外，研究人员利用这项技术研究生物体内的新陈代谢过程，提供关于不同物质如何在生物系统中相互作用的见解。此外，环境科学家使用无色差磁质谱仪监测空气、水和土壤中的污染物。通过准确识别和量化有害物质，该仪器为环境保护工作做出了重要贡献。它提供快速结果的能力使其成为监管机构和研究机构的宝贵工具。总之，无色差磁质谱仪代表了分析仪器领域的一项非凡成就。其独特的设计和功能使科学家能够以空前的准确性进行详细分析。随着技术的不断发展，我们可以期待质谱技术的进一步改进，为各个科学领域的新发现铺平道路。无色差磁质谱仪的持续发展无疑将增强我们对复杂化学相互作用的理解，并促进健康、安全和环境可持续性的进步。