dominant wave length

简明释义

吱长

英英释义

例句

1.In this experiment, we measured the dominant wave length of the sound waves produced by the vibrating string.

在这个实验中，我们测量了振动弦产生的声波的主波长。

2.The dominant wave length of the light emitted by the laser is crucial for its applications in communication.

激光发出的光的主波长对于其在通信中的应用至关重要。

3.Understanding the dominant wave length of ocean waves can help improve coastal engineering.

理解海浪的主波长可以帮助改善沿海工程。

4.The dominant wave length in this spectrum indicates the primary color of the light source.

这个光谱中的主波长指示了光源的主要颜色。

5.The dominant wave length of a color can affect how it is perceived by the human eye.

颜色的主波长会影响人眼对其的感知。

作文

The concept of dominant wave length is crucial in various scientific fields, particularly in physics and optics. It refers to the specific wavelength that is most prominent or intense in a given light source or wave pattern. Understanding this term can significantly enhance our comprehension of how light interacts with different materials and how it is perceived by the human eye.In the realm of optics, the dominant wave length plays a vital role in color perception. For instance, when we observe a rainbow, each color corresponds to a different wavelength of light. The red light has a longer wavelength, while blue light has a shorter wavelength. The dominant wave length of a particular color is what our eyes detect and interpret, allowing us to see the vivid spectrum of colors in nature.Moreover, the dominant wave length is essential in the study of lasers. Different lasers emit light at specific wavelengths, which determines their applications. For example, a helium-neon laser emits light primarily at a dominant wave length of 632.8 nanometers, producing a red beam that is widely used in various technologies, including barcode scanners and laser pointers. Understanding the dominant wave length helps scientists and engineers select the appropriate laser for their specific needs.In addition to its applications in optics, the dominant wave length is also significant in the field of environmental science. For instance, when studying the absorption of light by water bodies, researchers often measure the dominant wave length of sunlight that penetrates the water. This information is crucial for understanding photosynthesis in aquatic plants and the overall health of marine ecosystems. By analyzing the dominant wave length of light absorbed by different organisms, scientists can gain insights into their growth patterns and ecological interactions.Furthermore, the dominant wave length has implications in the field of telecommunications. Optical fibers transmit data using light, and the efficiency of this transmission depends on the dominant wave length of the light used. Engineers must carefully choose the dominant wave length to minimize signal loss and maximize data transfer rates. This selection is critical for developing high-speed internet connections and improving communication technologies.In conclusion, the term dominant wave length encompasses a wide range of applications across multiple disciplines. From understanding color perception in optics to its significance in environmental science and telecommunications, the dominant wave length serves as a fundamental concept that enhances our understanding of the natural world and technological advancements. As we continue to explore the properties of light and its interactions, grasping the importance of the dominant wave length will undoubtedly lead to further innovations and discoveries in science and technology.

“主波长”这一概念在多个科学领域中至关重要，特别是在物理学和光学中。它指的是在给定光源或波动模式中最突出或强烈的特定波长。理解这个术语可以显著增强我们对光如何与不同材料相互作用以及人眼如何感知光的理解。在光学领域，“主波长”在颜色感知中发挥着重要作用。例如，当我们观察彩虹时，每种颜色对应于光的不同波长。红光具有较长的波长，而蓝光则具有较短的波长。特定颜色的“主波长”就是我们眼睛检测并解释的内容，使我们能够看到自然界中生动的色谱。此外，“主波长”在激光研究中也至关重要。不同的激光以特定的波长发射光，这决定了它们的应用。例如，氦氖激光器主要在632.8纳米的“主波长”下发出光，产生红色光束，被广泛用于各种技术中，包括条形码扫描仪和激光指示器。理解“主波长”帮助科学家和工程师选择适合其特定需求的激光。除了在光学中的应用外，“主波长”在环境科学领域也很重要。例如，在研究水体光吸收时，研究人员通常测量穿透水面的阳光的“主波长”。这些信息对于理解水生植物的光合作用和海洋生态系统的整体健康至关重要。通过分析不同生物吸收的“主波长”光，科学家可以深入了解它们的生长模式和生态相互作用。此外，“主波长”在电信领域也有重要意义。光纤使用光传输数据，传输的效率取决于所使用光的“主波长”。工程师必须仔细选择“主波长”，以最小化信号损失并最大化数据传输速率。这一选择对于开发高速互联网连接和改善通信技术至关重要。总之，“主波长”这一术语涵盖了多个学科的广泛应用。从理解光学中的颜色感知到其在环境科学和电信中的重要性，“主波长”作为一个基本概念，增强了我们对自然世界和技术进步的理解。随着我们继续探索光的性质及其相互作用，掌握“主波长”的重要性无疑将导致科学和技术的进一步创新和发现。