thermal growth

简明释义

热生长

英英释义

例句

1.The thermal growth 热生长 of oxide layers can significantly affect the performance of electronic devices.

氧化层的 thermal growth 热生长 会显著影响电子设备的性能。

2.The thermal growth 热生长 of crystals can be controlled by adjusting temperature and pressure.

通过调整温度和压力，可以控制晶体的 thermal growth 热生长 。

3.Researchers are studying thermal growth 热生长 to improve the efficiency of solar cells.

研究人员正在研究 thermal growth 热生长 以提高太阳能电池的效率。

4.In the field of materials science, understanding thermal growth 热生长 mechanisms is crucial for developing new materials.

在材料科学领域，理解 thermal growth 热生长 机制对开发新材料至关重要。

5.The process of thermal growth 热生长 is essential in the manufacturing of high-quality semiconductors.

在高质量半导体的制造中，thermal growth 热生长 的过程至关重要。

作文

The concept of thermal growth refers to the expansion of materials as they are heated. This phenomenon is critical in various fields, including engineering, physics, and materials science. When a material is subjected to an increase in temperature, its particles gain energy and move apart, causing the material to expand. Understanding thermal growth is essential for designing structures that can withstand temperature fluctuations without sustaining damage.For instance, consider the construction of bridges. Bridges are often made from metal and concrete, both of which experience thermal growth when temperatures rise. If engineers do not account for this expansion, the structural integrity of the bridge could be compromised. Expansion joints are often incorporated into bridge designs to allow for the movement caused by thermal growth. These joints enable the bridge to expand and contract without cracking or buckling.In addition to civil engineering, thermal growth plays a significant role in the manufacturing of electronic devices. As electronic components heat up during operation, they also undergo thermal growth. If the materials used in the construction of these devices do not have compatible thermal expansion coefficients, it can lead to failures, such as solder joint fractures or component misalignment. Therefore, engineers must carefully select materials that will behave predictably under varying thermal conditions.Moreover, the study of thermal growth extends to the field of meteorology. Atmospheric scientists analyze how different materials absorb and emit heat, influencing weather patterns and climate change. For example, urban areas, with their concrete and asphalt surfaces, tend to retain heat more than rural areas, leading to what is known as the urban heat island effect. Understanding how thermal growth affects urban environments can help city planners implement strategies to mitigate heat retention and improve overall livability.The implications of thermal growth are not limited to engineering and environmental science; they also extend to everyday life. Cooking is a practical example where thermal growth is observed. When food is heated, it expands, affecting cooking times and methods. Chefs must understand how different ingredients react to heat to achieve the desired texture and flavor.In conclusion, thermal growth is a fundamental concept that impacts various disciplines and aspects of life. From engineering and manufacturing to environmental science and cooking, recognizing and understanding the effects of thermal growth can lead to better designs, improved safety, and enhanced quality of life. As we continue to innovate and develop new technologies, the importance of considering thermal growth will only grow, underscoring the need for interdisciplinary collaboration in tackling complex challenges. By embracing this knowledge, we can create a more resilient and adaptable future for all.

“热膨胀”这一概念指的是材料在加热时的膨胀现象。这种现象在工程、物理和材料科学等多个领域中至关重要。当材料受到温度升高的影响时，其颗粒获得能量并相互远离，导致材料膨胀。理解“热膨胀”对设计能够承受温度波动而不受损伤的结构至关重要。例如，考虑桥梁的建设。桥梁通常由金属和混凝土制成，这两种材料在温度升高时都会经历“热膨胀”。如果工程师没有考虑这种膨胀，桥梁的结构完整性可能会受到损害。扩展接头通常被纳入桥梁设计中，以允许因“热膨胀”造成的运动。这些接头使桥梁能够在不破裂或弯曲的情况下膨胀和收缩。除了土木工程，“热膨胀”在电子设备制造中也起着重要作用。当电子元件在运作过程中升温时，它们也会经历“热膨胀”。如果用于这些设备建造的材料没有兼容的热膨胀系数，就可能导致故障，例如焊点断裂或元件错位。因此，工程师必须仔细选择在不同热条件下表现可预测的材料。此外，“热膨胀”的研究还延伸到气象学领域。大气科学家分析不同材料如何吸收和发射热量，从而影响天气模式和气候变化。例如，城市地区由于其混凝土和沥青表面，往往比农村地区更容易保留热量，导致所谓的城市热岛效应。理解“热膨胀”如何影响城市环境，可以帮助城市规划者实施减轻热量保留并改善整体宜居性的策略。“热膨胀”的影响不仅限于工程和环境科学，它还延伸到日常生活。烹饪是一个观察“热膨胀”的实际例子。当食物加热时，它会膨胀，影响烹饪时间和方法。厨师必须了解不同成分对热量的反应，以达到所需的质地和风味。总之，“热膨胀”是一个基本概念，影响着各个学科和生活的各个方面。从工程和制造到环境科学和烹饪，认识和理解“热膨胀”的影响可以带来更好的设计、提高安全性和改善生活质量。随着我们不断创新和开发新技术，考虑“热膨胀”的重要性只会增加，强调了跨学科合作在解决复杂挑战中的必要性。通过接受这一知识，我们可以为所有人创造一个更具韧性和适应性的未来。