residual interaction

简明释义

剩余相互酌

英英释义

例句

1.Engineers must consider residual interaction 残余相互作用 when designing materials that will be subjected to stress.

工程师在设计会承受压力的材料时，必须考虑到残余相互作用。

2.The residual interaction 残余相互作用 in chemical reactions can lead to unexpected results during experiments.

化学反应中的残余相互作用可能导致实验中的意外结果。

3.In the study of complex systems, researchers often analyze the effects of residual interaction 残余相互作用 between particles after initial forces have been applied.

在复杂系统的研究中，研究人员通常分析在施加初始力后，粒子之间的残余相互作用的影响。

4.In psychological studies, the residual interaction 残余相互作用 between different variables can complicate the analysis.

在心理学研究中，不同变量之间的残余相互作用可能会使分析变得复杂。

5.The residual interaction 残余相互作用 in social networks can influence user behavior even after the main factors are accounted for.

在社交网络中的残余相互作用可以影响用户行为，即使在考虑了主要因素之后。

作文

In the realm of physics and chemistry, the term residual interaction refers to the remaining forces that exist between particles after the primary interactions have been accounted for. These interactions can significantly influence the behavior of systems at a molecular or atomic level, impacting properties such as stability, reactivity, and phase transitions. Understanding residual interaction is crucial for scientists and researchers as they strive to predict and manipulate the outcomes of chemical reactions and physical processes.For instance, in the study of materials science, the residual interaction between atoms in a crystal lattice can determine the material's mechanical strength and thermal conductivity. When designing new materials, engineers must consider not only the primary bonds that hold the atoms together but also the subtle effects of residual interaction that may alter the material’s overall performance. This understanding allows for the development of innovative products with tailored properties, such as lightweight yet strong composites used in aerospace applications.Moreover, in the field of quantum mechanics, residual interaction plays a pivotal role in the behavior of particles. Quantum systems often exhibit complex behaviors that cannot be fully explained by initial interactions alone. The residual interaction can lead to phenomena such as entanglement, where particles become interconnected in ways that transcend classical physics. This has profound implications for technologies like quantum computing and quantum cryptography, where understanding and harnessing these interactions is essential for advancing the field.In biological systems, residual interaction is equally important. Proteins, for example, fold into specific shapes that are determined not only by their primary amino acid sequences but also by the residual interactions among the various parts of the molecule. These interactions can dictate how proteins function and interact with other biomolecules, influencing processes such as enzyme activity and cellular signaling. By studying residual interaction, biochemists can gain insights into disease mechanisms and develop targeted therapies that address the underlying causes of conditions like cancer and neurodegenerative diseases.Furthermore, the concept of residual interaction extends beyond the natural sciences into social sciences and economics. In these fields, residual interaction can refer to the lingering effects of past interactions between individuals or groups, which can influence future behavior and decisions. For example, in negotiations, the residual feelings from previous discussions can impact the willingness of parties to collaborate or compromise. Understanding these dynamics is crucial for effective communication and conflict resolution.In conclusion, the term residual interaction encapsulates a wide range of phenomena across various disciplines. Whether in the context of physical sciences, biology, or social dynamics, recognizing the significance of these interactions helps us to better understand complex systems and improve our ability to predict and influence their behavior. As research continues to evolve, the study of residual interaction will undoubtedly remain a vital area of inquiry, shedding light on the intricate connections that shape our world.

在物理和化学领域，术语residual interaction指的是在主要相互作用被考虑后，粒子之间存在的剩余力。这些相互作用可以显著影响分子或原子层面上系统的行为，影响诸如稳定性、反应性和相变等性质。理解residual interaction对科学家和研究人员至关重要，因为他们努力预测和操纵化学反应和物理过程的结果。例如，在材料科学的研究中，晶格中原子之间的residual interaction可以决定材料的机械强度和热导率。在设计新材料时，工程师必须考虑不仅是将原子结合在一起的主要键，还要考虑可能改变材料整体性能的微妙residual interaction。这种理解使得研发具有定制属性的创新产品成为可能，例如用于航空航天应用的轻质而坚固的复合材料。此外，在量子力学领域，residual interaction在粒子的行为中起着关键作用。量子系统通常表现出复杂的行为，这些行为无法仅通过初始相互作用来完全解释。residual interaction可能导致诸如纠缠等现象，其中粒子以超越经典物理的方式相互关联。这对量子计算和量子密码学等技术具有深远的影响，在这些领域，理解和利用这些相互作用对于推动该领域的发展至关重要。在生物系统中，residual interaction同样重要。例如，蛋白质折叠成特定形状，这不仅由其主要氨基酸序列决定，还由分子各部分之间的剩余相互作用决定。这些相互作用可以决定蛋白质的功能及其与其他生物分子的相互作用，影响酶活性和细胞信号传导等过程。通过研究residual interaction，生物化学家可以深入了解疾病机制，并开发针对疾病根本原因的靶向疗法，如癌症和神经退行性疾病。此外，residual interaction的概念超越了自然科学，延伸到社会科学和经济学。在这些领域中，residual interaction可以指个人或群体之间过去相互作用的持续影响，这可能影响未来的行为和决策。例如，在谈判中，先前讨论的残余情感可能影响各方的合作或妥协意愿。理解这些动态对于有效沟通和冲突解决至关重要。总之，术语residual interaction涵盖了各个学科中的广泛现象。无论是在物理科学、生物学还是社会动态的背景下，认识到这些相互作用的重要性有助于我们更好地理解复杂系统，并提高我们预测和影响其行为的能力。随着研究的不断发展，residual interaction的研究无疑将继续成为一个重要的探究领域，揭示塑造我们世界的复杂联系。