mean mass range
简明释义
平均质量射程
英英释义
例句
1.We calculated the mean mass range to ensure accurate predictions in our simulations.
我们计算了平均质量范围以确保在我们的模拟中做出准确预测。
2.In our analysis, we focused on the mean mass range of the isotopes present in the sample.
在我们的分析中,我们专注于样品中存在的同位素的平均质量范围。
3.The results indicated a significant variation within the mean mass range of the tested compounds.
结果表明,在测试化合物的平均质量范围内存在显著变化。
4.The experiment measured the particles within the mean mass range of 10 to 100 daltons.
实验测量了在平均质量范围为10到100道尔顿的粒子。
5.The mean mass range of the molecules was critical for understanding their behavior in different environments.
分子的平均质量范围对于理解它们在不同环境中的行为至关重要。
作文
In the field of physics and engineering, understanding various properties of materials is essential for innovation and development. One such property that researchers often encounter is the concept of mean mass range. The term mean mass range refers to the average mass of a collection of particles or objects within a specified range. This metric is crucial when analyzing the behavior of materials under different conditions, such as temperature, pressure, and external forces. By calculating the mean mass range, scientists can predict how substances will react in various environments, which is vital for applications ranging from construction to aerospace engineering.For instance, consider the manufacturing of composite materials, which are widely used in industries like automotive and aerospace. Engineers must understand the mean mass range of the fibers and resins used in these composites to ensure they achieve the desired strength and durability. If the mean mass range of the components is too low, the material may not withstand the stresses it encounters during use. Conversely, if the mass is too high, the product may become excessively heavy, leading to inefficiencies in fuel consumption and performance.Moreover, the mean mass range is also significant in the field of chemistry, particularly in mass spectrometry. In this context, the mean mass range helps scientists identify and quantify different molecules present in a sample. By analyzing the mean mass range of ions produced during the ionization process, researchers can deduce the composition of complex mixtures. This understanding is crucial for applications such as drug development, environmental monitoring, and food safety, where precise measurements can lead to better outcomes.Understanding the mean mass range also has implications in the realm of astrophysics. When studying celestial bodies, astronomers often need to calculate the mean mass range of stars within a galaxy. This information helps them understand the distribution of mass in the universe and the formation of galaxies. By examining the mean mass range of different star types, researchers can make predictions about stellar evolution and the lifecycle of galaxies, contributing to our broader understanding of the cosmos.In conclusion, the concept of mean mass range is integral to numerous scientific disciplines. Its applications span from materials science to chemistry and astrophysics, illustrating its importance in both theoretical research and practical applications. By grasping the significance of the mean mass range, students and professionals alike can enhance their understanding of how mass influences the behavior of various systems. As we continue to explore the intricacies of the natural world, the mean mass range will undoubtedly remain a key parameter in our scientific toolkit, guiding us toward new discoveries and innovations.
在物理和工程领域,理解各种材料的性质对于创新和发展至关重要。研究人员经常遇到的一个概念是平均质量范围。术语平均质量范围指的是在特定范围内一组粒子或物体的平均质量。这个指标在分析材料在不同条件下的行为时至关重要,例如温度、压力和外部力。通过计算平均质量范围,科学家可以预测物质在各种环境中的反应,这对从建筑到航空航天工程等应用至关重要。例如,考虑复合材料的制造,这些材料广泛用于汽车和航空航天等行业。工程师必须了解这些复合材料中纤维和树脂的平均质量范围,以确保它们达到所需的强度和耐久性。如果组件的平均质量范围过低,材料可能无法承受使用过程中遇到的压力。相反,如果质量过高,产品可能会变得过于沉重,从而导致燃料消耗和性能的低效。此外,平均质量范围在化学领域,特别是在质谱分析中也很重要。在这种情况下,平均质量范围帮助科学家识别和量化样品中存在的不同分子。通过分析在电离过程中产生的离子的平均质量范围,研究人员可以推断复杂混合物的成分。这种理解对药物开发、环境监测和食品安全等应用至关重要,精确的测量可以带来更好的结果。理解平均质量范围在天体物理学领域也有重要意义。当研究天体时,天文学家通常需要计算银河系中恒星的平均质量范围。这些信息帮助他们理解宇宙中质量的分布和星系的形成。通过检查不同类型恒星的平均质量范围,研究人员可以预测恒星演化和星系生命周期,为我们更广泛地理解宇宙做出贡献。总之,平均质量范围的概念在众多科学学科中是不可或缺的。它的应用跨越了材料科学、化学和天体物理学,展示了它在理论研究和实际应用中的重要性。通过掌握平均质量范围的重要性,学生和专业人士可以增强对质量如何影响各种系统行为的理解。随着我们继续探索自然世界的复杂性,平均质量范围无疑将继续成为我们科学工具箱中的关键参数,引导我们走向新的发现和创新。
