dominant wave length

简明释义

吱长

英英释义

例句

1.The dominant wave length of the ocean waves can influence coastal erosion patterns.

海浪的主波长可以影响海岸侵蚀模式。

2.The laser emits light at a specific dominant wave length, which determines its color.

激光以特定的主波长发出光，这决定了它的颜色。

3.The dominant wave length of sunlight is crucial for understanding photosynthesis in plants.

阳光的主波长对于理解植物的光合作用至关重要。

4.In spectroscopy, the dominant wave length of a substance can reveal its chemical composition.

在光谱学中，物质的主波长可以揭示其化学成分。

5.Different materials absorb light at different dominant wave lengths, affecting their appearance.

不同材料在不同的主波长下吸收光，从而影响其外观。

作文

The concept of dominant wave length plays a crucial role in various fields of science, particularly in physics and optics. Understanding this term requires a grasp of the basic principles of wave behavior. In simple terms, the dominant wave length refers to the specific length of a wave that is most prominent or significant in a given context. For instance, when we talk about light, different colors correspond to different wave lengths. The dominant wave length determines the color that we perceive. In nature, many phenomena can be explained by examining the dominant wave length. For example, the blue color of the ocean is primarily due to the dominant wave length of light that water absorbs and scatters. Water absorbs longer wavelengths, such as reds and yellows, while shorter wavelengths like blue are scattered, giving the ocean its characteristic hue. This principle not only applies to bodies of water but also to the atmosphere, where the scattering of light results in the blue sky during the day.In the field of technology, the concept of dominant wave length is essential in telecommunications. Fiber optic cables, for example, transmit data using light waves, and the efficiency of this transmission can depend heavily on the dominant wave length used. Engineers often select specific wave lengths that minimize loss and maximize the speed of data transmission. This selection process is vital for ensuring that communication systems function effectively and reliably.Moreover, the dominant wave length is significant in the realm of medical imaging. Techniques such as MRI and ultrasound rely on understanding wave properties to produce clear images of the human body. Each imaging technique utilizes different wave lengths to optimize the clarity and detail of the resulting images. By adjusting the dominant wave length, medical professionals can enhance their diagnostic capabilities, leading to better patient outcomes.In art and design, the dominant wave length can influence how we perceive color and light in various mediums. Artists often consider the dominant wave length when choosing colors for their work. The way colors interact and the emotions they evoke can be deeply affected by the wave lengths present in a piece of art. For example, warm colors with shorter wave lengths can create feelings of warmth and energy, while cooler colors with longer wave lengths may evoke calmness and serenity.To summarize, the term dominant wave length encapsulates a fundamental aspect of wave behavior that has wide-ranging implications across multiple disciplines. From natural phenomena to technological advancements and artistic expression, understanding the dominant wave length enhances our comprehension of the world around us. By exploring this concept further, we can appreciate the intricate relationships between light, color, and their effects on our daily lives. As we continue to study and apply this knowledge, the importance of the dominant wave length will undoubtedly remain a pivotal topic in both scientific inquiry and practical application.

“主波长”的概念在科学的各个领域中都扮演着重要角色，特别是在物理学和光学中。理解这个术语需要掌握波行为的基本原理。简单来说，“主波长”指的是在特定上下文中最显著或重要的波的长度。例如，当我们谈论光时，不同的颜色对应不同的波长。“主波长”决定了我们所感知的颜色。在自然界中，许多现象可以通过检查“主波长”来解释。例如，海洋的蓝色主要是由于水吸收和散射光的“主波长”。水吸收较长的波长，如红色和黄色，而较短的波长如蓝色则被散射，赋予海洋其特征的色调。这一原理不仅适用于水体，也适用于大气，在白天光的散射导致天空呈现蓝色。在技术领域，“主波长”的概念在电信中至关重要。例如，光纤电缆通过光波传输数据，而这种传输的效率在很大程度上依赖于所使用的“主波长”。工程师通常选择特定的波长，以最小化损失并最大化数据传输速度。这个选择过程对于确保通信系统有效可靠地运行至关重要。此外，“主波长”在医学成像领域也很重要。MRI和超声等技术依赖于对波特性的理解，以产生清晰的人体图像。每种成像技术利用不同的波长来优化生成图像的清晰度和细节。通过调整“主波长”，医疗专业人员可以增强诊断能力，从而改善患者的结果。在艺术和设计中，“主波长”可以影响我们在各种媒介中对颜色和光的感知。艺术家在选择作品的颜色时常常考虑“主波长”。颜色之间的相互作用及其引发的情感可能会受到作品中存在的波长的深刻影响。例如，具有较短波长的暖色调可以创造出温暖和活力的感觉，而具有较长波长的冷色调则可能引发平静和宁静。总之，“主波长”这一术语概括了波行为的一个基本方面，这在多个学科中具有广泛的意义。从自然现象到技术进步，再到艺术表现，理解“主波长”增强了我们对周围世界的理解。通过进一步探索这一概念，我们能够欣赏光、颜色及其对我们日常生活影响之间的复杂关系。随着我们继续研究和应用这些知识，“主波长”的重要性无疑将继续成为科学探究和实际应用中的一个关键主题。