separation excitation

简明释义

他励

英英释义

例句

1.The team used separation excitation 分离激发 to create a new state of matter in their experiments.

团队在实验中使用了separation excitation 分离激发来创造一种新的物质状态。

2.In quantum mechanics, separation excitation 分离激发 plays a crucial role in understanding electron transitions.

在量子力学中，separation excitation 分离激发在理解电子跃迁中起着关键作用。

3.During the experiment, the separation excitation 分离激发 led to unexpected results that challenged existing theories.

在实验过程中，separation excitation 分离激发导致了意想不到的结果，这挑战了现有理论。

4.Understanding separation excitation 分离激发 is essential for advancements in photonics technology.

理解separation excitation 分离激发对光子技术的进步至关重要。

5.The researchers observed that the separation excitation 分离激发 significantly increased the energy levels of the particles.

研究人员观察到，separation excitation 分离激发显著提高了粒子的能量水平。

作文

In the realm of physics and engineering, the concept of separation excitation plays a crucial role in understanding various phenomena related to wave mechanics and material interactions. To grasp the significance of this term, it is essential to break it down into its components. The word 'separation' refers to the act of dividing or moving apart, while 'excitation' relates to the process of stimulating or energizing a system. When combined, separation excitation can be understood as the stimulation that occurs when two or more entities are separated, often leading to a change in their energy states or physical properties.One of the most common applications of separation excitation can be found in the field of quantum mechanics. In quantum systems, particles can exist in superposition states, where they exhibit properties of both separation and excitation simultaneously. When a measurement is made or an external force is applied, the system experiences separation excitation, causing the particles to transition to distinct energy levels. This phenomenon is fundamental in technologies such as quantum computing and quantum cryptography, where the manipulation of qubits relies on the principles of separation excitation.Moreover, separation excitation is also significant in the study of materials under stress. For instance, when a solid material is subjected to external forces, the internal structure may experience separation at the atomic or molecular level. This separation can lead to excitation of the atoms, resulting in changes in the material's properties, such as conductivity, elasticity, or even phase transitions. Understanding how separation excitation affects materials is vital for developing new technologies, including stronger alloys and advanced composites used in aerospace and automotive industries.Additionally, separation excitation has implications in biological systems. For example, in cellular biology, the process of cell division involves the separation of chromosomes, which can be viewed as a form of separation excitation. During mitosis, the chromosomes are separated and moved to opposite poles of the cell, a process that requires energy and precise coordination. Disruptions in this process can lead to various diseases, including cancer, highlighting the importance of understanding separation excitation in biological research.Furthermore, separation excitation can also be observed in everyday life, particularly in the context of sound waves. When a sound source moves away from an observer, the frequency of the sound waves changes due to the separation between the source and the observer. This phenomenon, known as the Doppler effect, is a practical illustration of separation excitation in action, affecting how we perceive sound in various situations, from passing vehicles to distant thunder.In conclusion, the term separation excitation encompasses a wide range of phenomena across multiple disciplines, including physics, materials science, and biology. By understanding the principles behind separation excitation, researchers and engineers can develop innovative solutions to complex problems, enhancing our technological capabilities and deepening our understanding of the natural world. As we continue to explore the intricacies of separation and excitation, the potential applications and implications of this concept will undoubtedly expand, paving the way for new discoveries and advancements in science and technology.

在物理和工程领域，separation excitation的概念在理解与波动力学和材料相互作用相关的各种现象中发挥着至关重要的作用。要掌握这个术语的重要性，有必要将其分解为组成部分。“分离”一词指的是分开或移动的行为，而“激发”则与刺激或使系统充能的过程有关。当结合在一起时，separation excitation可以理解为当两个或多个实体被分开时发生的刺激，通常导致它们的能量状态或物理特性的变化。separation excitation最常见的应用之一可以在量子力学领域找到。在量子系统中，粒子可以存在于叠加态中，在这种状态下，它们同时表现出分离和激发的特性。当进行测量或施加外力时，系统经历separation excitation，导致粒子过渡到不同的能量水平。这种现象是量子计算和量子密码学等技术的基础，其中量子位的操控依赖于separation excitation的原理。此外，separation excitation在研究受力材料时也具有重要意义。例如，当固体材料受到外部力时，内部结构可能在原子或分子层面经历分离。这种分离可能导致原子的激发，从而导致材料特性（如导电性、弹性甚至相变）的变化。理解separation excitation如何影响材料对于开发新技术至关重要，包括用于航空航天和汽车工业的更强合金和先进复合材料。此外，separation excitation在生物系统中也有重要意义。例如，在细胞生物学中，细胞分裂过程涉及染色体的分离，这可以看作是一种separation excitation。在有丝分裂过程中，染色体被分离并移动到细胞的相对两极，这一过程需要能量和精确的协调。此过程的扰动可能导致各种疾病，包括癌症，突显了理解生物研究中separation excitation的重要性。此外，separation excitation也可以在日常生活中观察到，特别是在声音波的背景下。当声源远离观察者时，由于声源和观察者之间的分离，声波的频率会发生变化。这种现象被称为多普勒效应，是separation excitation在实际应用中的一个例子，影响我们在各种情况下对声音的感知，从经过的车辆到遥远的雷声。总之，术语separation excitation涵盖了多个学科中的广泛现象，包括物理学、材料科学和生物学。通过理解separation excitation背后的原理，研究人员和工程师可以开发创新解决方案来应对复杂问题，增强我们的技术能力，加深我们对自然世界的理解。随着我们继续探索分离和激发的复杂性，这一概念的潜在应用和影响无疑会扩大，为科学和技术的新发现和进步铺平道路。