thermal response
简明释义
热反应
英英释义
The reaction or change in temperature of a material or system when subjected to thermal energy, such as heat transfer or changes in environmental temperature. | 在受到热能(如热传递或环境温度变化)影响时,材料或系统的反应或温度变化。 |
例句
1.Understanding the thermal response of the ocean is crucial for predicting climate change.
理解海洋的热响应对预测气候变化至关重要。
2.The thermal response of the material was tested under various environmental conditions.
该材料的热响应在各种环境条件下进行了测试。
3.The thermal response of the soil affects how quickly it heats up during the day.
土壤的热响应影响其白天加热的速度。
4.In this experiment, we measured the thermal response of different materials to assess their insulation properties.
在这个实验中,我们测量了不同材料的热响应以评估它们的绝缘性能。
5.The engineer analyzed the building's thermal response to ensure it could withstand extreme temperatures.
工程师分析了建筑物的热响应,以确保它能够承受极端温度。
作文
The concept of thermal response refers to the way materials react to changes in temperature. This phenomenon is crucial in various fields, including engineering, environmental science, and architecture. Understanding thermal response allows us to design better buildings, create more efficient machines, and predict natural phenomena with greater accuracy.In engineering, for instance, the thermal response of materials is a key factor in determining how structures will perform under different thermal conditions. When temperatures rise or fall, materials expand or contract, which can lead to stress and potential failure if not properly accounted for. Engineers must consider the thermal response of materials when designing bridges, roads, and buildings to ensure safety and longevity.Similarly, in environmental science, understanding the thermal response of ecosystems is vital for predicting how climate change will affect biodiversity. For example, as global temperatures rise, many species may struggle to adapt to new thermal environments. By studying the thermal response of various organisms, scientists can better understand which species are at risk and develop strategies for conservation.In architecture, the thermal response of a building is essential for energy efficiency. Architects must consider how the materials they choose will respond to heat from the sun and other sources. A well-designed building will minimize heat loss in the winter and reduce heat gain in the summer, ultimately leading to lower energy costs and a smaller carbon footprint. Innovations such as green roofs and thermal mass materials are examples of how architects can utilize the principles of thermal response to create sustainable designs.Moreover, the thermal response is also significant in the context of climate science. Researchers study how different surfaces—like oceans, forests, and urban areas—respond to heat. For instance, urban heat islands exhibit a unique thermal response due to the concentration of buildings and asphalt, which absorb and retain heat. Understanding these patterns helps city planners develop strategies to mitigate heat effects, such as increasing green spaces and improving building materials.Furthermore, advancements in technology have allowed for more precise measurements of thermal response. With tools like infrared thermography, scientists can visualize heat distribution across various surfaces, providing insights into how materials behave under thermal stress. This technology has applications in many areas, from identifying heat leaks in buildings to monitoring the health of electronic devices.In conclusion, the thermal response of materials and systems is a fundamental concept that influences multiple disciplines. Whether in engineering, environmental science, architecture, or technology, understanding how different entities respond to thermal changes is crucial for innovation and sustainability. As we continue to face challenges related to climate change and resource management, the importance of studying thermal response will only grow, guiding us toward a more resilient future.
“热响应”这一概念指的是材料对温度变化的反应方式。这一现象在工程、环境科学和建筑等多个领域至关重要。理解“热响应”使我们能够设计更好的建筑,创造更高效的机器,并更准确地预测自然现象。例如,在工程学中,材料的“热响应”是决定结构在不同热条件下表现的关键因素。当温度升高或降低时,材料会膨胀或收缩,如果没有适当考虑,这可能导致应力和潜在故障。因此,工程师在设计桥梁、道路和建筑时,必须考虑材料的“热响应”,以确保安全和耐久性。同样,在环境科学中,理解生态系统的“热响应”对于预测气候变化将如何影响生物多样性至关重要。例如,随着全球气温上升,许多物种可能难以适应新的热环境。通过研究各种生物的“热响应”,科学家可以更好地了解哪些物种面临风险,并制定保护策略。在建筑学中,建筑的“热响应”对能源效率至关重要。建筑师必须考虑他们选择的材料如何对来自太阳和其他来源的热量做出反应。设计良好的建筑将在冬季最小化热损失,并在夏季减少热增益,最终导致较低的能源成本和较小的碳足迹。绿色屋顶和热质量材料等创新是建筑师如何利用“热响应”原理来创造可持续设计的例子。此外,“热响应”在气候科学的背景下也很重要。研究人员研究不同表面(如海洋、森林和城市区域)对热量的反应。例如,城市热岛由于建筑和沥青的集中而表现出独特的“热响应”,这些材料吸收和保持热量。理解这些模式有助于城市规划者制定减轻热效应的策略,例如增加绿地和改善建筑材料。此外,技术的进步使得对“热响应”的更精确测量成为可能。借助红外热成像等工具,科学家可以可视化各种表面的热分布,提供关于材料在热应力下行为的见解。这项技术在多个领域都有应用,从识别建筑中的热泄漏到监测电子设备的健康。总之,材料和系统的“热响应”是一个基本概念,影响多个学科。无论是在工程、环境科学、建筑还是技术领域,理解不同实体如何响应热变化对于创新和可持续性至关重要。随着我们继续面临与气候变化和资源管理相关的挑战,研究“热响应”的重要性只会增加,引导我们走向一个更具韧性的未来。
相关单词
