resonance line
简明释义
谐振谱线
英英释义
例句
1.The researchers measured the resonance line shift to study the effects of external magnetic fields.
研究人员测量共振线的偏移以研究外部磁场的影响。
2.In spectroscopy, identifying the resonance line is crucial for determining the chemical composition of a sample.
在光谱学中,识别共振线对确定样品的化学成分至关重要。
3.Adjusting the frequency to match the resonance line enhances the efficiency of the system.
调整频率以匹配共振线可以提高系统的效率。
4.The resonance line of hydrogen can be observed in the emission spectrum of stars.
氢的共振线可以在恒星的发射光谱中观察到。
5.The physicist used a laser to excite the atoms at the resonance line to observe their behavior.
物理学家使用激光激发原子在共振线上以观察它们的行为。
作文
In the field of physics and engineering, the term resonance line refers to a specific frequency at which a system tends to oscillate with greater amplitude. This phenomenon is crucial in various applications, including telecommunications, music, and structural engineering. Understanding the concept of a resonance line can help us appreciate how certain frequencies can influence the behavior of different systems. For instance, in telecommunications, engineers often design circuits that resonate at particular frequencies to enhance signal strength and clarity. By tuning into the resonance line, they can minimize noise and interference, ensuring that the transmitted signals are received clearly. In music, the resonance line is equally significant. Musical instruments produce sound through vibrations, and each instrument has its unique set of resonance frequencies. When a musician plays an instrument, they aim to hit these frequencies to produce a rich and full sound. The resonance line of an instrument can be altered by changing its shape, material, or size, demonstrating the importance of this concept in the art of music. Moreover, in structural engineering, understanding the resonance line is vital for designing buildings and bridges that can withstand earthquakes and other forces. Structures have natural frequencies at which they vibrate, and if these frequencies match the frequencies of external forces, resonance can occur, leading to potential failure. Engineers must carefully analyze and design structures to avoid such situations by ensuring that their resonance lines do not coincide with the frequencies of expected external forces. The implications of the resonance line extend beyond technical fields. In everyday life, we encounter various systems that exhibit resonance. For example, a swing has a natural frequency at which it swings most efficiently. Pushing a swing at its resonance line allows it to gain maximum height with minimal effort. This principle can be observed in many physical systems, highlighting the pervasive nature of resonance in our world. In conclusion, the concept of the resonance line plays a critical role in multiple disciplines, from physics and engineering to music and everyday life. By understanding how resonance works, we can harness its effects to improve technology, create beautiful music, and design safer structures. The study of resonance lines not only enhances our scientific knowledge but also enriches our appreciation of the world around us, reminding us of the intricate connections between different domains of knowledge. As we continue to explore the principles of resonance, we may uncover even more applications and insights that can benefit society as a whole.
在物理和工程领域,术语共振线指的是一个系统倾向于以更大幅度振荡的特定频率。这种现象在电信、音乐和结构工程等多个应用中至关重要。理解共振线的概念可以帮助我们欣赏某些频率如何影响不同系统的行为。例如,在电信领域,工程师通常设计在特定频率上共振的电路,以增强信号的强度和清晰度。通过调谐到共振线,他们可以最小化噪声和干扰,确保传输的信号被清晰接收。在音乐中,共振线同样重要。乐器通过振动产生声音,每种乐器都有其独特的共振频率。当音乐家演奏乐器时,他们旨在击打这些频率,以产生丰富而饱满的声音。乐器的共振线可以通过改变其形状、材料或大小来改变,展示了这一概念在音乐艺术中的重要性。此外,在结构工程中,理解共振线对于设计能够抵御地震和其他力量的建筑物和桥梁至关重要。结构有自然频率,在这些频率下它们振动,如果这些频率与外部力量的频率匹配,就会发生共振,导致潜在的失败。工程师必须仔细分析和设计结构,以避免这种情况,确保它们的共振线与预期外部力量的频率不重合。共振线的影响超出了技术领域。在日常生活中,我们遇到许多表现出共振的系统。例如,秋千有一个自然频率,在这个频率下它最有效地摆动。在其共振线上推秋千,可以让它以最小的努力获得最大的高度。这个原则可以在许多物理系统中观察到,突显了共振在我们世界中的普遍性。总之,共振线的概念在多个学科中发挥着关键作用,从物理和工程到音乐和日常生活。通过理解共振如何运作,我们可以利用其效果来改善技术、创造美妙的音乐和设计更安全的结构。对共振线的研究不仅增强了我们的科学知识,还丰富了我们对周围世界的欣赏,提醒我们不同知识领域之间的复杂联系。当我们继续探索共振的原理时,我们可能会发现更多的应用和见解,这些都能使整个社会受益。
