dissociation laser

简明释义

离解激光器

英英释义

例句

1.In the lab, we observed how the dissociation laser affected the chemical reactions.

在实验室中，我们观察到解离激光如何影响化学反应。

2.The research team used a dissociation laser to break molecular bonds in their experiments.

研究小组使用解离激光在实验中打破分子键。

3.The dissociation laser was crucial for identifying the isotopes present in the sample.

解离激光对于识别样本中存在的同位素至关重要。

4.The dissociation laser technology has revolutionized the field of spectroscopy.

解离激光技术彻底改变了光谱学领域。

5.By applying a dissociation laser, they were able to analyze the components of the gas mixture.

通过应用解离激光，他们能够分析气体混合物的成分。

作文

The field of laser technology has seen remarkable advancements over the past few decades, leading to various applications in science and industry. One of the most intriguing developments is the use of the dissociation laser (解离激光), which plays a crucial role in breaking molecular bonds and facilitating chemical reactions. This essay will explore the principles behind dissociation lasers (解离激光), their applications, and their significance in modern science.To understand dissociation lasers (解离激光), it is essential to first grasp the concept of molecular dissociation. Molecular dissociation refers to the process where molecules break apart into smaller fragments, often resulting in the formation of free radicals. This process can be triggered by various means, including heat, radiation, or chemical reactions. However, lasers offer a highly controlled and efficient method for inducing dissociation, making them an invaluable tool in both research and industrial settings.A dissociation laser (解离激光) typically emits high-energy photons that are precisely tuned to match the energy levels of specific molecular bonds. When these photons interact with a molecule, they can provide enough energy to overcome the binding forces holding the atoms together. As a result, the molecule breaks apart, allowing scientists to study the resulting fragments and their behaviors. This technique is particularly useful in fields such as chemistry, physics, and materials science, where understanding molecular interactions is crucial.One of the significant applications of dissociation lasers (解离激光) is in the field of spectroscopy. By using a dissociation laser (解离激光) to selectively break down molecules, researchers can analyze the fragments produced to gain insights into the original molecular structure. This information is vital for developing new materials, pharmaceuticals, and understanding complex biological processes. Additionally, the ability to control the dissociation process allows for precise manipulation of chemical reactions, leading to more efficient and targeted synthesis methods.Moreover, dissociation lasers (解离激光) have found applications in environmental science as well. For instance, they can be used to study pollutants in the atmosphere by breaking down complex molecules into identifiable components. This capability enables scientists to monitor air quality and understand the chemical processes occurring in our environment. Furthermore, dissociation lasers (解离激光) can aid in the development of cleaner technologies by facilitating the breakdown of harmful substances into less toxic forms.In conclusion, the advent of dissociation lasers (解离激光) represents a significant leap forward in our ability to manipulate and understand molecular structures. Their applications span across various fields, from fundamental research to practical industrial uses. As technology continues to evolve, it is likely that the capabilities and applications of dissociation lasers (解离激光) will expand even further, opening new avenues for discovery and innovation. The future holds great promise for this fascinating technology, and its impact on science and society will undoubtedly be profound.

激光技术领域在过去几十年中取得了显著进展，导致其在科学和工业中的各种应用。其中一个最引人注目的发展是使用解离激光（dissociation laser），它在打破分子键和促进化学反应方面发挥着至关重要的作用。本文将探讨解离激光（dissociation laser）背后的原理、应用及其在现代科学中的重要性。要理解解离激光（dissociation laser），首先必须掌握分子解离的概念。分子解离是指分子分裂成更小的碎片的过程，通常会形成自由基。这个过程可以通过多种方式触发，包括热、辐射或化学反应。然而，激光提供了一种高度控制和有效的方法来诱导解离，使其成为研究和工业环境中不可或缺的工具。解离激光（dissociation laser）通常发出高能光子，这些光子的能量精确调谐以匹配特定分子键的能量水平。当这些光子与分子相互作用时，它们可以提供足够的能量来克服保持原子结合的力。因此，分子断裂，允许科学家研究产生的碎片及其行为。这项技术在化学、物理和材料科学等领域尤为有用，在这些领域中，理解分子之间的相互作用至关重要。解离激光（dissociation laser）的一个重要应用是在光谱学领域。通过使用解离激光（dissociation laser）选择性地分解分子，研究人员可以分析产生的碎片，以获得关于原始分子结构的见解。这些信息对于开发新材料、药物以及理解复杂的生物过程至关重要。此外，能够控制解离过程使得化学反应的精确操控成为可能，从而导致更高效和更具针对性的合成方法。此外，解离激光（dissociation laser）在环境科学中也找到了应用。例如，它们可以用于通过分解复杂分子为可识别的成分来研究大气中的污染物。这种能力使科学家能够监测空气质量并理解我们环境中发生的化学过程。此外，解离激光（dissociation laser）可以帮助开发更清洁的技术，通过促进有害物质的分解为较少毒性的形式。总之，解离激光（dissociation laser）的出现代表了我们操纵和理解分子结构能力的重大飞跃。它们的应用跨越多个领域，从基础研究到实际工业用途。随着技术的不断发展，解离激光（dissociation laser）的能力和应用可能会进一步扩展，为发现和创新开辟新的途径。未来对这项迷人技术充满希望，其对科学和社会的影响无疑将是深远的。