coefficient of temperature

简明释义

温度系数

英英释义

例句

1.The coefficient of temperature 温度系数 for this material indicates how much it will expand when heated.

该材料的温度系数 coefficient of temperature 表明它在加热时会膨胀多少。

2.For accurate measurements, calibrate your instruments using the coefficient of temperature 温度系数 of the sensor.

为了准确测量，使用传感器的温度系数 coefficient of temperature 校准您的仪器。

3.A high coefficient of temperature 温度系数 means the material will change dimensions significantly with temperature changes.

高温度系数 coefficient of temperature意味着该材料在温度变化时会显著改变尺寸。

4.The coefficient of temperature 温度系数 is crucial in the manufacturing of thermometers.

在温度计的制造中，温度系数 coefficient of temperature 是至关重要的。

5.Engineers must consider the coefficient of temperature 温度系数 when designing components that will be exposed to varying temperatures.

工程师在设计将暴露于不同温度的部件时，必须考虑温度系数 coefficient of temperature。

作文

The concept of the coefficient of temperature plays a crucial role in various scientific and engineering fields. It refers to the measure of how a physical property, such as the length of an object or the resistance of a material, changes with temperature. Understanding the coefficient of temperature is essential for predicting the behavior of materials under different thermal conditions.For instance, when dealing with metals, the coefficient of temperature can provide insights into how much a metal will expand when heated. This property is particularly important in construction and manufacturing, where precise measurements are necessary to ensure safety and functionality. If engineers do not account for the expansion of materials due to temperature changes, structures could suffer from stress and potentially catastrophic failures.Moreover, the coefficient of temperature is not limited to just physical dimensions. It also applies to electrical properties. For example, the resistance of a conductor typically increases with temperature. This phenomenon is quantified by the temperature coefficient of resistance, which is a specific type of coefficient of temperature. In electronic circuits, understanding this relationship helps engineers design components that can operate efficiently across a range of temperatures.In the field of thermodynamics, the coefficient of temperature is vital for understanding heat transfer processes. When analyzing systems, scientists often need to know how the temperature affects the properties of gases and liquids. The ideal gas law, for example, incorporates temperature as a key variable, and its behavior is closely linked to the coefficient of temperature. By studying how gases react to changes in temperature, researchers can develop better models for predicting weather patterns, designing engines, and even launching spacecraft.Additionally, the coefficient of temperature is significant in the context of climate science. As global temperatures rise, understanding how different materials and natural systems respond to these changes becomes increasingly important. For example, the thermal expansion of ice and water is a critical factor in predicting sea-level rise. Scientists use the coefficient of temperature to model how ice sheets will behave as the planet warms, which has direct implications for coastal communities around the world.In conclusion, the coefficient of temperature is a fundamental concept that transcends multiple disciplines. Whether in engineering, electronics, thermodynamics, or environmental science, recognizing how temperature influences various properties is essential for innovation and safety. As we continue to face challenges related to climate change and technological advancement, a thorough understanding of the coefficient of temperature will remain indispensable for researchers and practitioners alike.

“温度系数”这一概念在多个科学和工程领域中扮演着至关重要的角色。它指的是某一物理属性（例如物体的长度或材料的电阻）随温度变化的程度。理解“温度系数”对于预测材料在不同热条件下的行为至关重要。例如，在处理金属时，“温度系数”可以提供有关金属在加热时会膨胀多少的见解。这一特性在建筑和制造中尤为重要，因为精确的测量对于确保安全和功能至关重要。如果工程师没有考虑材料因温度变化而导致的膨胀，结构可能会承受压力并可能发生灾难性的故障。此外，“温度系数”不仅限于物理尺寸。它同样适用于电气特性。例如，导体的电阻通常随着温度的升高而增加。这种现象通过电阻的温度系数来量化，这是“温度系数”的一种特定类型。在电子电路中，理解这种关系有助于工程师设计能够在各种温度范围内高效运行的组件。在热力学领域，“温度系数”对于理解热传递过程至关重要。在分析系统时，科学家通常需要知道温度如何影响气体和液体的性质。理想气体定律例如，包含温度作为一个关键变量，其行为与“温度系数”密切相关。通过研究气体如何对温度变化作出反应，研究人员可以制定更好的模型，以预测天气模式、设计发动机，甚至发射航天器。此外，“温度系数”在气候科学中也很重要。随着全球气温上升，理解不同材料和自然系统如何响应这些变化变得越来越重要。例如，冰和水的热膨胀是预测海平面上升的关键因素。科学家使用“温度系数”来建模当地球变暖时冰盖的行为，这对全球沿海社区具有直接影响。总之，“温度系数”是一个基本概念，跨越多个学科。无论是在工程、电子学、热力学还是环境科学中，认识到温度如何影响各种属性对创新和安全至关重要。随着我们继续面临与气候变化和技术进步相关的挑战，充分理解“温度系数”将始终对研究人员和从业者至关重要。