total ionization

简明释义

全电离

英英释义

例句

1.In the field of plasma physics, total ionization 完全电离 is crucial for understanding the behavior of charged particles.

在等离子体物理学中，完全电离 对理解带电粒子的行为至关重要。

2.The researchers aimed to achieve total ionization 完全电离 in their study on laser-induced breakdown spectroscopy.

研究人员在激光诱导击穿光谱学研究中目标是实现完全电离。

3.The experiment demonstrated that the laser could achieve total ionization 完全电离 of the gas within milliseconds.

实验表明激光可以在毫秒内实现气体的完全电离。

4.When the energy input exceeds a certain threshold, total ionization 完全电离 can occur rapidly.

当能量输入超过某一阈值时，完全电离 可以迅速发生。

5.The application of strong electromagnetic fields can lead to total ionization 完全电离 of atoms in a gas.

强电磁场的应用可以导致气体中原子的完全电离。

作文

In the field of chemistry and physics, the term total ionization refers to a process where all atoms or molecules in a sample lose their electrons completely, resulting in the formation of ions. This phenomenon is crucial for understanding various reactions and processes, particularly in the context of plasma physics, analytical chemistry, and environmental science. When we talk about total ionization, we often consider its implications in different scientific applications, such as mass spectrometry, where ionization is necessary for the detection and analysis of substances.One of the most significant areas where total ionization plays a vital role is in the study of gases under high-energy conditions. For instance, when a gas is subjected to extremely high temperatures, the energy supplied can lead to total ionization. In this state, the gas transforms into plasma, which is considered the fourth state of matter. Plasma consists of free electrons and ions, allowing it to conduct electricity and respond to electromagnetic fields. This characteristic makes plasma essential in various applications, including fluorescent lights, plasma TVs, and even in nuclear fusion research.Moreover, total ionization is also significant in the realm of astrophysics. In stars, the immense pressure and temperature lead to conditions where hydrogen and helium undergo total ionization, contributing to the star's energy production through nuclear fusion. Understanding this process is fundamental to comprehending how stars evolve and how they generate the energy that sustains life on Earth.In analytical chemistry, total ionization is critical for the accurate measurement and identification of compounds. Techniques such as mass spectrometry rely on the ability to ionize a sample completely to analyze its composition. By achieving total ionization, chemists can obtain precise data regarding the molecular weight and structure of substances, which is invaluable in fields like pharmaceuticals, environmental monitoring, and forensic science.Furthermore, the concept of total ionization extends into environmental science, particularly in studying atmospheric chemistry. Here, researchers examine how pollutants can undergo ionization in the atmosphere, affecting air quality and climate change. The understanding of these processes helps in developing strategies to mitigate pollution and protect the environment.To summarize, total ionization is a crucial concept across various scientific disciplines. From its role in forming plasma in high-energy environments to its application in analytical techniques and its importance in astrophysics and environmental studies, the implications of total ionization are vast and significant. As scientists continue to explore the intricacies of ionization processes, our understanding of the universe, matter, and the environment will undoubtedly deepen, leading to advancements in technology and science that can benefit society as a whole.

在化学和物理学领域，术语total ionization指的是一个过程，其中样本中的所有原子或分子完全失去电子，从而形成离子。这种现象对于理解各种反应和过程至关重要，特别是在等离子体物理、分析化学和环境科学的背景下。当我们谈论total ionization时，我们通常考虑其在不同科学应用中的影响，例如质谱分析，在该过程中，离子化对于检测和分析物质是必要的。total ionization发挥重要作用的最显著领域之一是研究高能条件下的气体。例如，当气体受到极高温度的影响时，所提供的能量可能导致total ionization。在这种状态下，气体转变为等离子体，这被认为是物质的第四种状态。等离子体由自由电子和离子组成，使其能够导电并响应电磁场。这一特性使得等离子体在各种应用中至关重要，包括荧光灯、等离子电视，甚至在核聚变研究中。此外，total ionization在天体物理学领域也具有重要意义。在恒星内部，巨大的压力和温度导致氢和氦经历total ionization，通过核聚变过程为恒星的能量生产做出贡献。理解这一过程对于理解恒星如何演化以及它们如何产生维持地球生命的能量至关重要。在分析化学中，total ionization对于准确测量和识别化合物至关重要。质谱等技术依赖于能够完全离子化样本以分析其组成。通过实现total ionization，化学家可以获得有关物质分子量和结构的精确数据，这在制药、环境监测和法医学等领域非常宝贵。此外，total ionization的概念延伸到环境科学，特别是在研究大气化学时。在这里，研究人员考察污染物如何在大气中发生离子化，从而影响空气质量和气候变化。理解这些过程有助于制定减轻污染和保护环境的策略。总之，total ionization是各个科学学科中的一个关键概念。从它在高能环境中形成等离子体的作用，到它在分析技术中的应用，以及它在天体物理学和环境研究中的重要性，total ionization的影响广泛而重要。随着科学家继续探索离子化过程的复杂性，我们对宇宙、物质和环境的理解无疑会加深，从而推动技术和科学的进步，造福整个社会。