irradiative

简明释义

英[ɪˈreɪdɪˌeɪtɪv]美[ɪˈreɪdɪˌeɪtɪv]

adj. 会发光的；有放射力的；有启发作用的

英英释义

单词用法

同义词

反义词

例句

1.The larger is the output power of laser, the shorter is the irradiative time of impairment ear bone and cochlea.

激光输出功率密度愈大，损伤听骨和耳蜗的照射时间愈短。

2.The larger is the output power of laser, the shorter is the irradiative time of impairment ear bone and cochlea.

激光输出功率密度愈大，损伤听骨和耳蜗的照射时间愈短。

3.The irradiative 辐射的 cooling effect in urban areas can help mitigate heat islands.

城市地区的irradiative 辐射的 冷却效果可以帮助缓解热岛效应。

4.In nuclear physics, understanding irradiative 辐射的 processes is crucial for safety protocols.

在核物理中，理解irradiative 辐射的 过程对安全协议至关重要。

5.Astronomers study the irradiative 辐射的 emissions from stars to understand their life cycles.

天文学家研究恒星的irradiative 辐射的 发射，以了解它们的生命周期。

6.The researchers found that the irradiative 辐射的 effects of sunlight can significantly impact plant growth.

研究人员发现，阳光的irradiative 辐射的 效果可以显著影响植物生长。

7.The irradiative 辐射的 heat transfer in this material is higher than expected.

这种材料中的irradiative 辐射的 热传递高于预期。

作文

In the realm of physics and environmental science, the term irradiative refers to processes that involve the emission or transmission of energy in the form of radiation. This concept is crucial for understanding various natural phenomena, including climate change, energy transfer in ecosystems, and even the functioning of our daily technologies. To illustrate the significance of irradiative processes, let us delve into how they affect both our environment and our lives.Firstly, consider the role of solar radiation in sustaining life on Earth. The Sun emits energy in the form of electromagnetic radiation, which reaches our planet and is absorbed by land, water, and living organisms. This irradiative energy is essential for photosynthesis, the process by which plants convert sunlight into chemical energy. Without this irradiative input, life as we know it would not exist, as plants provide the oxygen we breathe and serve as the foundation of food webs.Moreover, the balance of irradiative energy on Earth plays a significant role in regulating our climate. The greenhouse effect, a natural phenomenon, occurs when certain gases in the atmosphere trap some of the irradiative energy emitted by the Earth's surface after it absorbs solar radiation. This process keeps our planet warm enough to support life. However, human activities have increased the concentration of greenhouse gases, leading to an enhanced greenhouse effect and global warming. Understanding the irradiative properties of different gases allows scientists to model climate change scenarios and develop strategies to mitigate its impacts.In addition to climate science, the concept of irradiative processes is also vital in the field of renewable energy. Solar panels, for instance, harness the irradiative energy from the sun and convert it into electricity. By capturing and utilizing this energy, we can reduce our reliance on fossil fuels and decrease greenhouse gas emissions. The efficiency of solar panels depends on their ability to absorb irradiative energy effectively, making advancements in solar technology crucial for a sustainable future.Furthermore, the medical field utilizes irradiative techniques for diagnostic and therapeutic purposes. For example, X-rays and radiation therapy are common practices in modern medicine. X-rays use irradiative energy to create images of the inside of the body, aiding in the diagnosis of various conditions. Similarly, radiation therapy targets cancer cells with high doses of irradiative energy to destroy them while minimizing damage to surrounding healthy tissue. These applications highlight the dual nature of irradiative processes, as they can be both beneficial and harmful depending on their context and dosage.In conclusion, the term irradiative encapsulates a wide range of phenomena that are integral to our understanding of the world. From the fundamental processes that sustain life to the advanced technologies that shape our future, irradiative energy plays a pivotal role. As we continue to explore and harness this energy, it is essential to remain mindful of its implications on our environment and health. Embracing sustainable practices and advancing our knowledge of irradiative processes will be key to addressing the challenges we face in the 21st century.

在物理学和环境科学领域，术语irradiative指的是涉及以辐射形式发射或传输能量的过程。这个概念对于理解各种自然现象至关重要，包括气候变化、生态系统中的能量转移，甚至是我们日常技术的运作。为了说明irradiative过程的重要性，让我们深入探讨它们如何影响我们的环境和生活。首先，考虑太阳辐射在维持地球生命中的作用。太阳以电磁辐射的形式发出能量，这些能量到达我们的星球并被陆地、水体和生物吸收。这种irradiative能量对光合作用至关重要，光合作用是植物将阳光转化为化学能的过程。如果没有这种irradiative输入，生命将无法存在，因为植物提供我们呼吸的氧气，并作为食物链的基础。此外，地球上irradiative能量的平衡在调节我们气候方面也起着重要作用。温室效应是一种自然现象，当大气中的某些气体捕获地球表面在吸收太阳辐射后发出的部分irradiative能量时，就会发生这种现象。这个过程使我们的星球保持足够温暖，以支持生命。然而，人类活动增加了温室气体的浓度，导致增强的温室效应和全球变暖。理解不同气体的irradiative特性使科学家能够模拟气候变化场景，并制定减轻其影响的策略。除了气候科学，irradiative过程的概念在可再生能源领域也是至关重要的。例如，太阳能电池板利用来自太阳的irradiative能量并将其转化为电力。通过捕获和利用这种能量，我们可以减少对化石燃料的依赖，并降低温室气体排放。太阳能电池板的效率取决于它们有效吸收irradiative能量的能力，因此推动太阳能技术的发展对于可持续未来至关重要。此外，医疗领域利用irradiative技术进行诊断和治疗。例如，X射线和放射治疗是现代医学中的常见做法。X射线利用irradiative能量创建身体内部图像，有助于诊断各种疾病。同样，放射治疗针对癌细胞，使用高剂量的irradiative能量摧毁它们，同时尽量减少对周围健康组织的损害。这些应用突显了irradiative过程的双重性质，因为它们在不同的背景和剂量下可能既有益又有害。总之，术语irradiative涵盖了广泛的现象，这些现象对于我们理解世界至关重要。从维持生命的基本过程到塑造我们未来的先进技术，irradiative能量发挥着关键作用。随着我们继续探索和利用这种能量，保持对其对环境和健康影响的关注至关重要。接受可持续实践并推动我们对irradiative过程的理解，将是应对21世纪面临挑战的关键。