antiparallel coupling

简明释义

反并联结法

英英释义

例句

1.In quantum mechanics, the concept of antiparallel coupling 反平行耦合 is crucial for understanding the behavior of spin systems.

在量子力学中，反平行耦合 antiparallel coupling 的概念对于理解自旋系统的行为至关重要。

2.When designing magnetic materials, engineers often consider antiparallel coupling 反平行耦合 to optimize performance.

在设计磁性材料时，工程师们常常考虑反平行耦合 antiparallel coupling 以优化性能。

3.The antiparallel coupling 反平行耦合 in ferromagnetic materials is essential for understanding their hysteresis behavior.

铁磁材料中的反平行耦合 antiparallel coupling 对于理解其滞回行为至关重要。

4.The antiparallel coupling 反平行耦合 of electron spins can lead to a significant reduction in magnetic energy.

电子自旋的反平行耦合 antiparallel coupling 可以显著降低磁能。

5.Researchers are exploring antiparallel coupling 反平行耦合 in nanostructures to enhance their magnetic properties.

研究人员正在探索纳米结构中的反平行耦合 antiparallel coupling 以增强其磁性。

作文

In the realm of physics and engineering, the concept of antiparallel coupling plays a crucial role in understanding how different systems interact with one another. To grasp this idea, it is essential to break down its components and explore their implications in various fields. Antiparallel coupling refers to a specific arrangement where two entities are aligned in opposite directions relative to each other. This configuration is often observed in the context of molecular biology, particularly in the structure of DNA, where the two strands run in opposite directions—one strand runs from the 5' to 3' direction, while the complementary strand runs from 3' to 5'. This antiparallel orientation is vital for the stability and replication of the DNA double helix.The significance of antiparallel coupling extends beyond biology and into the world of engineering, especially in the design of mechanical systems. For instance, in gear systems, when two gears are coupled in an antiparallel manner, the rotation of one gear will result in the opposite rotation of the other. This principle is fundamental in creating efficient machinery, as it allows for synchronized movements that can lead to enhanced performance and reduced wear on the components involved.Moreover, antiparallel coupling is also relevant in the field of electronics, particularly in the design of circuits. In certain configurations, electronic components may be arranged in an antiparallel fashion to achieve specific electrical characteristics. For example, diodes connected in an antiparallel arrangement can allow current to flow in both directions, which is essential in applications such as AC to DC conversion.Understanding antiparallel coupling is not only limited to theoretical knowledge; it has practical applications that can be observed in everyday life. From the DNA that carries the genetic information of all living organisms to the gears in a clock that keep time, the implications of this concept are vast and varied. Engineers, biologists, and physicists alike must consider the principles of antiparallel coupling when designing systems or studying interactions, as this alignment can significantly influence the behavior and efficiency of the system.In conclusion, antiparallel coupling is a fundamental concept that bridges multiple disciplines, illustrating the interconnectedness of scientific principles. By recognizing the importance of this arrangement, we can better appreciate the complexities of both natural and engineered systems. As we continue to explore the intricacies of our world, the understanding of concepts like antiparallel coupling will undoubtedly lead to more innovative solutions and advancements across various fields. Whether in the microscopic world of DNA or the macroscopic realm of machinery, the principles of antiparallel coupling remind us of the elegance and functionality inherent in opposing forces working in harmony.

在物理和工程领域，反向耦合的概念在理解不同系统如何相互作用方面发挥着至关重要的作用。要掌握这个思想，有必要分解其组成部分并探索它们在各个领域的影响。反向耦合指的是两个实体相对于彼此以相反方向排列的特定配置。这种配置通常在分子生物学的背景下观察到，特别是在DNA的结构中，其中两条链以相反的方向运行——一条链从5'到3'方向，而互补链从3'到5'方向运行。这种反向排列对DNA双螺旋的稳定性和复制至关重要。反向耦合的重要性不仅限于生物学，还延伸到工程领域，尤其是在机械系统的设计中。例如，在齿轮系统中，当两个齿轮以反向方式耦合时，一个齿轮的旋转将导致另一个齿轮的反向旋转。这一原理在创建高效的机械装置中是基础，因为它允许同步运动，从而提高性能并减少涉及组件的磨损。此外，反向耦合在电子学领域也相关，特别是在电路设计中。在某些配置中，电子元件可能以反向方式排列，以实现特定的电气特性。例如，连接在反向排列中的二极管可以允许电流双向流动，这在交流转直流转换等应用中至关重要。理解反向耦合不仅限于理论知识；它具有在日常生活中可观察到的实际应用。从携带所有生物体遗传信息的DNA到保持时间的钟表中的齿轮，这一概念的影响广泛而多样。工程师、生物学家和物理学家在设计系统或研究相互作用时必须考虑反向耦合的原理，因为这种排列会显著影响系统的行为和效率。总之，反向耦合是一个基本概念，连接多个学科，展示了科学原理的相互关联性。通过认识到这一排列的重要性，我们可以更好地欣赏自然和工程系统的复杂性。当我们继续探索我们世界的细微差别时，对像反向耦合这样概念的理解无疑将导致各个领域更具创新性的解决方案和进步。无论是在DNA的微观世界还是在机械的宏观领域，反向耦合的原理提醒我们，相反力量的和谐工作中蕴含的优雅和功能性。