atmospheric transmission band

简明释义

大气透射带

英英释义

例句

1.The atmospheric transmission band is crucial for satellite communication, allowing signals to pass through the Earth's atmosphere.

对于卫星通信来说，大气传输带至关重要，它允许信号穿过地球的大气层。

2.In remote sensing, understanding the atmospheric transmission band helps in accurately interpreting data collected from various wavelengths.

在遥感中，理解大气传输带有助于准确解释从不同波长收集的数据。

3.Researchers study the atmospheric transmission band to improve weather forecasting models.

研究人员研究大气传输带以改善天气预报模型。

4.The atmospheric transmission band affects how light from stars reaches our telescopes on Earth.

星光到达我们地球望远镜的过程中，大气传输带会影响光的传播。

5.Understanding the atmospheric transmission band is essential for designing effective optical instruments.

理解大气传输带对于设计有效的光学仪器至关重要。

作文

The study of light and its interaction with the Earth's atmosphere is a fascinating field that encompasses various scientific disciplines. One of the key concepts in this area is the atmospheric transmission band, which refers to specific ranges of wavelengths in the electromagnetic spectrum where radiation can pass through the atmosphere with minimal absorption or scattering. Understanding these bands is crucial for numerous applications, including satellite communication, remote sensing, and environmental monitoring.When we talk about the atmospheric transmission band, we are essentially discussing the portions of the spectrum that allow for effective transmission of energy from one point to another through the atmosphere. These bands are not uniform; they vary depending on several factors such as atmospheric composition, humidity, and the presence of pollutants. For instance, the visible light range, which is critical for human vision, falls within a certain atmospheric transmission band, allowing sunlight to reach the Earth's surface effectively.In the context of remote sensing, the identification of these bands is vital for the development of sensors that can accurately capture data about the Earth's surface. Different materials reflect and absorb light differently across various wavelengths. By focusing on the atmospheric transmission band where certain materials exhibit unique spectral signatures, scientists can determine their presence and concentration. This application is particularly important in fields like agriculture, where monitoring crop health through satellite imagery can lead to better yield predictions and resource management.Moreover, the atmospheric transmission band plays a significant role in climate studies. Scientists use data collected from satellites that operate within these bands to analyze changes in the Earth's climate system. For example, infrared bands are crucial for measuring the Earth’s temperature and identifying heat patterns. By understanding how greenhouse gases absorb radiation in these bands, researchers can make more accurate predictions about global warming and its potential impacts.However, it is important to note that the atmospheric transmission band is affected by human activities. Air pollution can introduce various particles and gases into the atmosphere, altering the transmission characteristics of certain wavelengths. This alteration can lead to challenges in both satellite observations and ground-based measurements, complicating our understanding of environmental processes. Therefore, continuous monitoring of atmospheric conditions is essential to ensure the reliability of data collected in these bands.In conclusion, the concept of the atmospheric transmission band is integral to our understanding of how light interacts with the atmosphere, impacting a wide range of scientific and practical applications. From enhancing satellite communication to improving environmental monitoring and climate research, grasping the significance of these bands allows us to harness the power of electromagnetic radiation effectively. As we continue to explore and expand our knowledge in this area, we are likely to uncover new insights that can help address pressing global issues such as climate change and resource management.

光及其与地球大气层相互作用的研究是一个迷人的领域，涵盖了多个科学学科。在这个领域中，一个关键概念是大气传输带，指的是电磁波谱中辐射以最小吸收或散射通过大气的特定波长范围。理解这些波段对于许多应用至关重要，包括卫星通信、遥感和环境监测。当我们谈论大气传输带时，我们实际上是在讨论允许能量从一个点有效传输到另一个点的光谱部分。这些波段并不均匀；它们因多种因素而异，如大气成分、湿度和污染物的存在。例如，紫外线范围在某个大气传输带内，这对人类视觉至关重要，使阳光能够有效地到达地球表面。在遥感的背景下，识别这些波段对开发能够准确捕捉地球表面数据的传感器至关重要。不同材料在各种波长上反射和吸收光的方式各不相同。通过专注于某些材料在特定大气传输带中表现出独特光谱特征的波段，科学家可以确定它们的存在和浓度。这一应用在农业等领域尤为重要，通过卫星图像监测作物健康可以更好地预测产量和资源管理。此外，大气传输带在气候研究中也发挥着重要作用。科学家利用在这些波段内操作的卫星收集的数据来分析地球气候系统的变化。例如，红外波段对测量地球温度和识别热模式至关重要。通过了解温室气体在这些波段中吸收辐射的方式，研究人员可以更准确地预测全球变暖及其潜在影响。然而，重要的是要注意，大气传输带受人类活动的影响。空气污染会将各种颗粒和气体引入大气中，改变某些波长的传输特性。这种变化可能导致卫星观测和地面测量中的挑战，复杂化我们对环境过程的理解。因此，持续监测大气条件对于确保在这些波段收集的数据的可靠性至关重要。总之，大气传输带的概念对我们理解光如何与大气相互作用至关重要，影响着广泛的科学和实际应用。从增强卫星通信到改善环境监测和气候研究，掌握这些波段的重要性使我们能够有效利用电磁辐射的力量。随着我们继续探索和扩展这一领域的知识，我们可能会发现新的见解，帮助解决气候变化和资源管理等紧迫的全球问题。