isochore
简明释义
n. [物] 等容线;[热] 等体积线
英英释义
单词用法
等容过程 | |
等容条件 | |
等容热容量 | |
等容变换 |
同义词
| 等温线 | The isotherm on the map indicates areas with the same temperature. | 地图上的等温线表示温度相同的区域。 | |
| 等压线 | 气象学家使用等压线来分析天气模式。 | ||
| 等焓线 | In thermodynamics, an isoenthalp process maintains constant enthalpy. | 在热力学中,等焓过程保持焓恒定。 |
反义词
| 等温线 | 等温线图显示了温度相等的区域。 | ||
| 等压线 | An isobar indicates regions of equal atmospheric pressure on a weather map. | 等压线在天气地图上表示气压相等的区域。 |
例句
1.A map that displays isochores is an isochore map.
展示等层厚线的图即为等厚图。
2.The terms isopach and isopach map are incorrectly used interchangeably to describe isochores and isochore maps.
但术语等厚线和等厚线图互换使用地来描述等层厚线和等层厚线图是不正确的。
3.The terms isopach and isopach map are incorrectly used interchangeably to describe isochores and isochore maps.
但术语等厚线和等厚线图互换使用地来描述等层厚线和等层厚线图是不正确的。
4.The isochore map revealed unexpected variations in rock density.
等厚线图显示出岩石密度的意外变化。
5.The isochore indicates where the pressure is constant in a given geological formation.
等厚线指示在特定地质构造中压力恒定的区域。
6.The geologist mapped the isochore to determine the thickness of sedimentary layers.
地质学家绘制了等厚线以确定沉积层的厚度。
7.In the study of geothermal systems, the isochore helps identify areas of potential heat flow.
在地热系统研究中,等厚线有助于识别潜在的热流区域。
8.By analyzing the isochore, scientists can predict the movement of fluids in the Earth's crust.
通过分析等厚线,科学家可以预测地壳中流体的运动。
作文
In the field of thermodynamics, the concept of an isochore (等容线) plays a crucial role in understanding the behavior of gases under varying conditions. An isochore refers to a process or condition where the volume of a gas remains constant, regardless of changes in pressure and temperature. This principle is essential for scientists and engineers as it helps in predicting how gases will react when subjected to different external influences.To illustrate the significance of an isochore, consider a sealed container filled with gas. If this container is heated, the gas molecules inside gain energy and move more vigorously. Under normal circumstances, one would expect the pressure to increase as the temperature rises. However, if the gas is confined to a space where its volume cannot change, this situation exemplifies an isochore. In such a case, the relationship between pressure and temperature can be described by the ideal gas law, which states that pressure is directly proportional to temperature when volume is held constant.The study of isochores can lead to various practical applications. For instance, in the design of engines or refrigeration systems, understanding how gases behave at constant volume is vital. Engineers must ensure that these systems can handle changes in temperature without compromising their efficiency or safety. By applying the principles of isochores, they can predict how the system will respond under different operational conditions, thus optimizing performance.Moreover, the concept of an isochore is not limited to theoretical applications; it is also significant in natural processes. For example, the atmosphere exhibits isochoric behavior during certain weather phenomena. When air masses are trapped in a region with no opportunity for expansion, their temperature may rise due to solar heating while their volume remains unchanged. Meteorologists study these changes to forecast weather patterns accurately.Furthermore, the implications of isochores extend to environmental science. Understanding how gases behave under constant volume conditions can help researchers evaluate the impact of greenhouse gases on climate change. By analyzing how these gases interact with the environment, scientists can develop models to predict future climate scenarios and inform policy decisions.In conclusion, the concept of an isochore (等容线) is a fundamental aspect of thermodynamics that provides insight into the behavior of gases under constant volume conditions. Its applications span across various fields, including engineering, meteorology, and environmental science. As we continue to explore the complexities of gas behavior, the understanding of isochores will remain vital in addressing both practical challenges and scientific inquiries. The ability to maintain a comprehensive grasp of such concepts is essential for anyone involved in the sciences, as it lays the groundwork for innovation and discovery in our ever-evolving world.
在热力学领域,isochore(等容线)这一概念在理解气体在不同条件下的行为时起着至关重要的作用。isochore指的是一个过程或条件,其中气体的体积保持不变,无论压力和温度如何变化。这个原理对于科学家和工程师来说至关重要,因为它有助于预测气体在受到不同外部影响时的反应。为了说明isochore的重要性,可以考虑一个充满气体的密封容器。如果这个容器被加热,内部的气体分子会获得能量并更加剧烈地运动。在正常情况下,人们会期望随着温度的升高,压力也随之增加。然而,如果气体被限制在一个体积无法改变的空间中,这种情况就体现了isochore。在这种情况下,当体积保持不变时,压力和温度之间的关系可以通过理想气体定律来描述,即压力与温度成正比。对isochores的研究可以导致各种实际应用。例如,在发动机或制冷系统的设计中,理解气体在恒定体积下的行为至关重要。工程师必须确保这些系统能够在温度变化时处理,而不会影响其效率或安全性。通过应用isochores的原理,他们可以预测系统在不同操作条件下的反应,从而优化性能。此外,isochore的概念不仅限于理论应用;它在自然过程中也具有重要意义。例如,大气在某些天气现象中表现出isochoric行为。当空气团被困在一个没有扩展机会的区域时,由于太阳辐射加热,它们的温度可能上升,而体积保持不变。气象学家研究这些变化,以准确预测天气模式。此外,isochores的影响延伸到环境科学。理解气体在恒定体积条件下的行为可以帮助研究人员评估温室气体对气候变化的影响。通过分析这些气体与环境的相互作用,科学家可以开发模型以预测未来的气候情景,并为政策决策提供信息。总之,isochore(等容线)这一概念是热力学的基本方面,它提供了对气体在恒定体积条件下行为的深入了解。其应用跨越多个领域,包括工程、气象和环境科学。随着我们继续探索气体行为的复杂性,对isochores的理解将继续在应对实际挑战和科学探究中发挥重要作用。能够全面掌握这些概念对于任何从事科学工作的人来说至关重要,因为它为我们不断发展的世界中的创新和发现奠定了基础。
