atomistic 的英语释义:
adj. 原子规模的;微细的;精细的
atomistic 的发音:
/??t?m?st?k/
atomistic 的英语范文:
The atomistic approach is widely used in science and technology. It emphasizes the importance of small parts and details, and helps us to understand complex systems in a more comprehensive way. In engineering, for example, atomistic simulation is commonly used to predict the behavior of materials under extreme conditions. By studying the atomic structure of materials, engineers can develop more effective and reliable materials and processes.
In medicine, atomistic approaches have also been used to understand diseases at the molecular level. By studying the interactions between molecules and cells, researchers can identify new therapeutic targets and develop more targeted treatments for diseases.
However, atomistic approaches can also have limitations. For example, they may not be able to capture the interactions between different scales or systems that are not fully understood at the atomic level. Therefore, it is important to integrate atomistic approaches with other methods and tools to achieve a more comprehensive understanding of complex systems.
In conclusion, atomistic approaches are essential for understanding and addressing many of the challenges we face today. By using atomistic methods, we can develop more effective and sustainable solutions to complex problems.
Atomistic: An Atomic View of the World
In the world of atomistic physics, everything is made up of tiny particles, each with their own unique properties and behaviors. Similarly, in the world of engineering, we deal with systems that are made up of individual components or atoms, each with their own functions and interactions. Atomistic engineering is a discipline that focuses on studying and manipulating these components to achieve optimal performance and efficiency.
One of the key principles of atomistic engineering is the atomistic view of the world, which emphasizes the importance of studying individual components and their interactions in detail. This approach allows engineers to understand how each component affects the overall system, and how they can optimize their design to achieve the desired outcomes.
In my opinion, atomistic engineering is a powerful tool for innovation and progress. By studying individual components and their interactions, engineers can identify new opportunities for improvement and create innovative solutions that are tailored to specific needs. Furthermore, atomistic engineering emphasizes collaboration and cooperation between different disciplines, which promotes cross-fertilization of ideas and knowledge sharing.
In conclusion, atomistic engineering is a fundamental approach to understanding and manipulating systems made up of individual components or atoms. By adopting this approach, engineers can achieve optimal performance and efficiency, identify new opportunities for innovation, and promote collaboration and cooperation between different disciplines. I believe that atomistic engineering will continue to play an important role in the future development of technology and society.
atomistic
发音:英 [??t?m?st] 美 [??tɑ?m?st]
例句及释义:
"The atomistic approach is based on the idea that individual particles determine the properties of a system."
原子模型是基于每个粒子决定系统属性的想法。
atomistic 英语范文:
The atomistic world is composed of countless particles, each with its own unique properties and behaviors. In this world, we can observe the interactions between particles and how they affect the overall system. The atomistic approach is essential in understanding the fundamental principles of physics and chemistry, as well as in engineering and technology. It allows us to analyze complex systems at a microscopic level and design materials and devices with precise control. However, atomistic modeling and simulation can be computationally expensive, requiring significant resources and time. Therefore, it is essential to develop efficient algorithms and methods to reduce the computational burden and improve accuracy. In conclusion, atomistic modeling is a powerful tool that can help us understand and design complex systems with precision.
以上范文围绕原子模型展开,强调了原子模型在物理学、化学、工程和技术中的重要性,以及在分析和设计复杂系统中的优势。同时,也提到了原子模型在计算上的高成本,需要开发高效的算法和方法来减轻计算负担和提高准确性。总的来说,原子模型是一个能够帮助我们精确理解和设计复杂系统的强大工具。
由于字数限制,以上范文仅为一个大概的框架,您可以在此基础上进行修改和扩展,以符合您的具体需求。
