radiative

简明释义

[ˈreɪdɪeɪtɪv][ˈreɪdɪˌeɪtɪv]

adj. 辐射的;放射的;发光的;放热的

英英释义

Relating to the emission or transmission of radiation, especially in the form of electromagnetic waves.

与辐射的发射或传输有关,尤其是以电磁波的形式。

Capable of emitting energy in the form of radiation.

能够以辐射形式发出能量。

单词用法

radiative transfer

辐射传输;辐射转移

radiative transfer equation

辐射传递方程

同义词

emissive

发射的

The emissive properties of the material allow it to emit energy in the form of radiation.

该材料的发射特性使其能够以辐射的形式发出能量。

radiant

辐射的

Radiant heat can be felt from a distance, such as from a fireplace.

辐射热可以从远处感受到,例如来自壁炉的热量。

thermal

热的

The thermal radiation emitted by the sun is essential for life on Earth.

太阳发出的热辐射对地球上的生命至关重要。

luminescent

发光的

Luminescent materials are used in various applications, including glow-in-the-dark items.

发光材料用于各种应用,包括夜光物品。

反义词

non-radiative

非辐射的

Non-radiative processes often dominate in certain materials, leading to energy losses.

在某些材料中,非辐射过程通常占主导地位,导致能量损失。

absorptive

吸收的

The absorptive properties of the material can affect its thermal performance.

材料的吸收特性可以影响其热性能。

例句

1.Detailed studies have been carried out to demonstrate the effects of the autoionization resonances on the radiative opacity and transmission.

研究了电离阈以上的自电离共振对光谱分辨的辐射不透明度和透射谱的影响。

2.The distribution of radiative heat flux to the combustor wall has been obtained by.

通过计算,获得了燃烧室壁面的辐射热流分布。

3.Radiative forcing will be affected deeply by the change of single scattering albedo of dust aerosol.

辐射强迫数值对矿物尘气溶胶单次散射反照率的变化较敏感。

4.Then, the total surface radiative forcing was simulated.

然后,进行地面总辐射强迫的模拟试验。

5.The climatic feedback magnifies the influence of aerosol vertical distribution on radiative and climatic effect.

气候系统的反馈作用会放大气溶胶垂直分布对辐射气候效应的影响。

6.The radiative temperature of a non-uniformly rectilinearly accelerating evaporating black hole is presented.

给出了作变加速直线运动的蒸发黑洞的辐射温度。

7.The discrete ordinate approximation method of three dimensional radiative transfer equation in absorbing scattering medium is expounded.

阐述了含吸收散射性介质三维空腔内辐射传递方程的离散坐标解法。

8.Many approximation methods have been proposed to solve radiative heat transfer problem in semitransparent media.

使用该方法分别求解了一维和二维半透明介质内的辐射换热问题。

9.Radiative transfer of infrared radiation through the atmosphere is an important geophysical process.

红外辐射在大气中的传输是重要的地球物理过程。

10.Scientists study radiative 辐射的 transfer to understand how heat moves through different materials.

科学家研究辐射的辐射的传递,以了解热量如何在不同材料中移动。

11.The sun emits energy through radiative 辐射的 processes, which is essential for life on Earth.

太阳通过辐射的辐射的过程释放能量,这对地球上的生命至关重要。

12.The radiative 辐射的 balance of a planet is crucial for maintaining its temperature and climate.

一个星球的辐射的辐射的平衡对维持其温度和气候至关重要。

13.In the context of climate change, radiative 辐射的 forcing refers to the difference in energy absorbed by the Earth and energy radiated back to space.

在气候变化的背景下,辐射的辐射的强迫指的是地球吸收的能量与辐射回太空的能量之间的差异。

14.The greenhouse effect is a result of radiative 辐射的 energy being trapped in the Earth's atmosphere.

温室效应是由于辐射的辐射的能量被困在地球大气中所导致的。

作文

The concept of energy transfer is fundamental to understanding various natural phenomena. One of the most intriguing forms of energy transfer is through processes that are described as radiative (辐射的). This term refers to the emission and transmission of energy in the form of electromagnetic waves, such as light and heat. In our everyday lives, we encounter radiative (辐射的) energy in numerous ways, from the warmth of the sun on our skin to the glow of a light bulb in a dark room.To appreciate the significance of radiative (辐射的) energy, we must first explore its role in our solar system. The sun, a massive ball of gas, generates energy through nuclear fusion. This energy is then released into space in the form of radiative (辐射的) energy. It takes about eight minutes for this energy to travel from the sun to Earth, where it sustains life by providing warmth and enabling photosynthesis in plants. Without this radiative (辐射的) energy, our planet would be a frozen wasteland devoid of life.Moreover, the principles of radiative (辐射的) energy transfer are crucial in fields such as meteorology and climate science. Scientists study how energy from the sun interacts with the Earth's atmosphere and surface to understand weather patterns and climate change. For instance, the greenhouse effect is a result of certain gases in the atmosphere trapping radiative (辐射的) energy, which leads to an increase in global temperatures. This phenomenon underscores the importance of monitoring radiative (辐射的) energy flows to predict future climate scenarios.In addition to natural processes, radiative (辐射的) energy also plays a significant role in technology. For example, in the field of telecommunications, data is transmitted using radiative (辐射的) signals. Radio waves, which are a type of electromagnetic radiation, carry information over long distances, allowing for wireless communication. Similarly, advancements in medical imaging techniques, such as X-rays and MRI scans, rely on radiative (辐射的) energy to visualize the internal structures of the body.Despite its many benefits, the radiative (辐射的) properties of energy can also pose risks. For instance, exposure to high levels of ionizing radiation, which is a form of radiative (辐射的) energy, can lead to serious health issues, including cancer. This highlights the need for safety measures and regulations to protect individuals from harmful radiative (辐射的) exposure in medical, industrial, and environmental contexts.In conclusion, the term radiative (辐射的) encompasses a wide range of phenomena related to the emission and transfer of energy. From the life-giving rays of the sun to the technological advancements in communication and medicine, radiative (辐射的) energy is integral to both nature and human innovation. As we continue to explore and harness the power of radiative (辐射的) energy, it is essential to remain mindful of its impacts on our environment and health. Understanding this complex interplay will enable us to make informed decisions about energy use and conservation in the future.

能量转移的概念是理解各种自然现象的基础。最令人着迷的能量转移形式之一是通过被描述为radiative(辐射的)过程。这一术语指的是以电磁波的形式发射和传输能量,例如光和热。在我们的日常生活中,我们以多种方式遇到radiative(辐射的)能量,从阳光照在我们皮肤上的温暖到黑暗房间里灯泡的光芒。要欣赏radiative(辐射的)能量的重要性,我们必须首先探讨其在太阳系中的作用。太阳,一个巨大的气体球,通过核聚变产生能量。然后,这种能量以radiative(辐射的)能量的形式释放到太空中。大约需要八分钟,这种能量才能从太阳传播到地球,在那里它通过提供温暖和促进植物的光合作用来维持生命。如果没有这种radiative(辐射的)能量,我们的星球将是一个冰冻的荒原,没有生命。此外,radiative(辐射的)能量转移的原理在气象学和气候科学等领域至关重要。科学家研究来自太阳的能量如何与地球的大气和表面相互作用,以了解天气模式和气候变化。例如,温室效应是由于大气中的某些气体捕获了radiative(辐射的)能量,导致全球温度升高。这一现象强调了监测radiative(辐射的)能量流动以预测未来气候情景的重要性。除了自然过程,radiative(辐射的)能量在技术中也发挥着重要作用。例如,在电信领域,数据通过radiative(辐射的)信号进行传输。无线电波,作为一种电磁辐射,能够远距离传递信息,从而实现无线通信。同样,医学成像技术的进步,如X射线和MRI扫描,也依赖于radiative(辐射的)能量来可视化身体的内部结构。尽管有许多好处,但radiative(辐射的)能量的特性也可能带来风险。例如,暴露于高水平的电离辐射,这是一种radiative(辐射的)能量,可能导致严重的健康问题,包括癌症。这突显了在医疗、工业和环境背景下保护个人免受有害radiative(辐射的)暴露的安全措施和法规的必要性。总之,术语radiative(辐射的)涵盖了与能量的发射和转移相关的广泛现象。从给予生命的阳光到通信和医学领域的技术进步,radiative(辐射的)能量是自然和人类创新的核心。随着我们继续探索和利用radiative(辐射的)能量的力量,重要的是要关注其对环境和健康的影响。理解这一复杂的相互作用将使我们能够对未来的能源使用和保护做出明智的决策。