field of excitation

简明释义

励磁场

英英释义

A field of excitation refers to a specific area or domain in which energy or stimuli induce a response or activation in a system, often used in physics and engineering contexts.

激发场指的是在特定区域或领域中,能量或刺激引起系统的反应或激活,通常用于物理和工程领域的上下文。

例句

1.The team studied the field of excitation generated by the laser to improve their imaging techniques.

团队研究了激光产生的激发场以改善他们的成像技术。

2.In physics, the concept of field of excitation is essential for explaining wave propagation.

在物理学中,激发场的概念对于解释波传播至关重要。

3.In the context of neuroscience, the field of excitation plays a crucial role in signal transmission between neurons.

在神经科学的背景下,激发场在神经元之间的信号传递中起着至关重要的作用。

4.The researchers focused on the field of excitation in quantum mechanics to understand particle behavior.

研究人员专注于量子力学中的激发场以理解粒子行为。

5.Understanding the field of excitation can help in developing better therapeutic strategies for epilepsy.

理解激发场有助于制定更好的癫痫治疗策略。

作文

In the realm of physics, particularly in the study of electromagnetism and quantum mechanics, the concept of a field of excitation plays a crucial role. This term refers to a region in which particles or fields exhibit increased energy or activity due to external influences. Understanding this concept is vital for grasping various phenomena, from the behavior of subatomic particles to the propagation of electromagnetic waves. One of the most significant applications of the field of excitation can be found in the field of quantum field theory. Here, particles are not considered as isolated entities but rather as excitations within their respective fields. For instance, an electron can be described as an excitation of the electron field. When we talk about the field of excitation, we are essentially discussing how energy is distributed and manifests in various forms within a given area of space.Moreover, the field of excitation is also relevant in the context of wave phenomena. When a wave travels through a medium, it creates regions of compression and rarefaction, which can be viewed as areas of excitation within that medium. This idea can be applied to sound waves, where variations in pressure create a field of excitation that our ears interpret as sound. Similarly, in optics, light can be seen as a wave propagating through a field of excitation that interacts with matter, leading to various optical effects.In technology, the understanding of the field of excitation has led to advancements in fields such as telecommunications and medical imaging. For example, Magnetic Resonance Imaging (MRI) relies on the principles of magnetic fields and the excitation of atomic nuclei. By applying a strong magnetic field, certain nuclei within the body can be excited, allowing for detailed imaging of internal structures. This application highlights the practical importance of comprehending how a field of excitation operates in real-world scenarios.Furthermore, the field of excitation concept extends beyond the physical sciences into areas such as psychology and education. In these fields, the term can metaphorically describe environments that stimulate learning and creativity. For instance, a classroom designed to foster engagement and curiosity can be seen as creating a field of excitation for students, encouraging them to explore and innovate. In this sense, the field of excitation becomes a powerful metaphor for any situation where energy and enthusiasm are fostered.In conclusion, the field of excitation is a multifaceted concept that spans various disciplines, from physics to psychology. Its implications are profound, influencing both theoretical frameworks and practical applications. By understanding the dynamics of a field of excitation, we can better appreciate the complexities of the universe and enhance our approaches to learning and innovation.

在物理学领域,尤其是在电磁学和量子力学的研究中,激发场的概念起着至关重要的作用。这个术语指的是由于外部影响,粒子或场在某个区域内表现出增加的能量或活动。理解这个概念对于掌握各种现象至关重要,从亚原子粒子的行为到电磁波的传播。激发场的一个重要应用可以在量子场论中找到。在这里,粒子并不被视为孤立的实体,而是各自场中的激发。例如,电子可以被描述为电子场的激发。当我们谈论激发场时,我们实际上是在讨论能量如何在给定空间区域内分布和表现。此外,激发场在波现象的背景下也很相关。当波通过介质传播时,它会在该介质中产生压缩和稀疏的区域,这可以看作是该介质内的激发区域。这个想法可以应用于声波,其中压力变化创造了一个激发场,我们的耳朵将其解读为声音。类似地,在光学中,光可以被视为通过与物质相互作用的激发场传播的波,从而导致各种光学效应。在技术领域,对激发场的理解促进了通信和医学成像等领域的进步。例如,磁共振成像(MRI)依赖于磁场原理和原子核的激发。通过施加强磁场,体内某些核可以被激发,从而允许对内部结构进行详细成像。这个应用突显了理解激发场在现实世界场景中运作的重要性。此外,激发场的概念超越了物理科学,延伸到心理学和教育等领域。在这些领域,这个术语可以隐喻地描述刺激学习和创造力的环境。例如,一个旨在促进参与和好奇心的教室可以被视为为学生创造了一个激发场,鼓励他们探索和创新。从这个意义上说,激发场成为任何激发能量和热情的情况的强大隐喻。总之,激发场是一个多方面的概念,跨越多个学科,从物理学到心理学。它的影响深远,影响理论框架和实际应用。通过理解激发场的动态,我们可以更好地欣赏宇宙的复杂性,并增强我们对学习和创新的方法。

相关单词

excitation

excitation详解:怎么读、什么意思、用法