isopiestic

简明释义

英[ˌaɪsəʊpaɪˈestɪk]美[ˌaɪsoʊpaɪˈestɪk]

[气象] 等压的

等压线

英英释义

单词用法

同义词

反义词

例句

1.The article includes three parts, which discuss networks "optimal design, networks" drawing process, and plot methods of isopiestic line respectively.

文章分三部分分别论述了管网的优化计算、管网图形的绘制和等压线图的绘制方法。

2.The article includes three parts, which discuss networks "optimal design, networks" drawing process, and plot methods of isopiestic line respectively.

文章分三部分分别论述了管网的优化计算、管网图形的绘制和等压线图的绘制方法。

3.The article includes three parts, which discuss network's calculation, and plot methods of isopiestic line respectively.

文章分三部分论述了管网的平差计算原理、管网图形的绘制和等压线图的绘制方法。

4.An isopiestic solution is essential for accurate measurements in osmotic pressure experiments.

在渗透压实验中，等渗溶液对于准确测量至关重要。

5.The isopiestic method allows for the determination of molar masses by comparing the vapor pressures of solutions.

等渗法通过比较溶液的蒸汽压力来确定摩尔质量。

6.To maintain isopiestic conditions during the experiment, the team used a specially designed calorimeter.

为了在实验中保持等渗条件，团队使用了专门设计的量热仪。

7.In thermodynamics, an isopiestic process is one where no heat is exchanged with the surroundings.

在热力学中，等渗过程是指与周围环境没有热量交换的过程。

8.The researchers conducted an experiment under isopiestic conditions to ensure that vapor pressure was equal throughout the system.

研究人员在等渗条件下进行实验，以确保系统内的蒸汽压力相等。

作文

The study of thermodynamics and its various principles is crucial in understanding the behavior of different substances under varying conditions. One of the intriguing concepts within this field is the notion of isopiestic systems. An isopiestic process refers to a scenario where two substances are in thermal equilibrium, meaning that there is no net heat transfer between them. This concept is particularly important in the context of solutions and mixtures, where the interactions between different components can significantly affect their properties. When we think about isopiestic systems, we often consider how they relate to the concept of vapor pressure. In an isopiestic environment, the vapor pressures of the involved substances remain constant, which implies that the system is at a stable state. This stability can be observed in various natural and industrial processes, such as distillation and crystallization, where maintaining a specific temperature and pressure is essential for achieving desired outcomes. Moreover, the significance of isopiestic conditions extends beyond mere theoretical implications. In practical applications, understanding these conditions can lead to better formulations in pharmaceuticals, food science, and environmental studies. For instance, in drug formulation, ensuring that a solution remains isopiestic can help maintain the efficacy of the medication, as changes in concentration can lead to precipitation or degradation of active ingredients. Similarly, in food preservation, controlling the moisture content and concentration of solutes can create an isopiestic environment that inhibits microbial growth, thereby extending shelf life. In addition to its practical applications, the study of isopiestic systems also opens up avenues for research. Scientists are continually exploring how different factors, such as temperature, pressure, and concentration, influence the isopiestic nature of solutions. Understanding these relationships can lead to advancements in material science, where the development of new materials with specific properties relies on the manipulation of isopiestic conditions. Furthermore, the relevance of isopiestic processes can be seen in environmental studies, particularly in understanding how pollutants interact with water bodies. The solubility and distribution of contaminants can be influenced by isopiestic conditions, affecting their bioavailability and toxicity. Researchers are increasingly focusing on these interactions to develop better strategies for remediation and pollution control. In conclusion, the concept of isopiestic systems is a fundamental aspect of thermodynamics that has far-reaching implications across various fields. From enhancing pharmaceutical formulations to improving food preservation techniques and advancing scientific research, the understanding of isopiestic conditions allows us to harness the principles of thermodynamics for practical and innovative applications. As we continue to explore the intricacies of these systems, the potential for new discoveries and advancements remains vast, highlighting the importance of thermodynamic principles in both theoretical and applied contexts.

热力学及其各种原理的研究对于理解不同物质在不同条件下的行为至关重要。在这个领域中，一个引人入胜的概念是等热（isopiestic）系统的概念。等热过程指的是两种物质处于热平衡的情形，这意味着它们之间没有净热量转移。这个概念在溶液和混合物的上下文中尤为重要，因为不同组分之间的相互作用可以显著影响它们的性质。当我们考虑等热（isopiestic）系统时，我们常常会想到它们与蒸汽压的关系。在一个等热环境中，参与物质的蒸汽压保持不变，这意味着系统处于稳定状态。这种稳定性可以在各种自然和工业过程中观察到，例如蒸馏和结晶，其中维持特定的温度和压力对于实现期望结果至关重要。此外，等热（isopiestic）条件的意义超越了单纯的理论含义。在实际应用中，理解这些条件可以导致制药、食品科学和环境研究中的更好配方。例如，在药物配方中，确保溶液保持等热（isopiestic）可以帮助维持药物的功效，因为浓度的变化可能导致活性成分的沉淀或降解。同样，在食品保鲜中，控制水分含量和溶质浓度可以创造一个等热（isopiestic）环境，从而抑制微生物生长，从而延长保质期。除了实际应用之外，研究等热（isopiestic）系统的研究也开辟了新的研究途径。科学家们不断探索温度、压力和浓度等不同因素如何影响溶液的等热（isopiestic）性质。理解这些关系可以促进材料科学的进步，其中开发具有特定性质的新材料依赖于对等热（isopiestic）条件的操控。此外，等热（isopiestic）过程的相关性可以在环境研究中看到，特别是在理解污染物与水体的相互作用方面。污染物的溶解度和分布可能受到等热（isopiestic）条件的影响，从而影响其生物可利用性和毒性。研究人员越来越关注这些相互作用，以制定更好的修复和污染控制策略。总之，等热（isopiestic）系统的概念是热力学的一个基本方面，具有广泛的跨学科影响。从增强药物配方到改善食品保鲜技术，再到推动科学研究，理解等热（isopiestic）条件使我们能够利用热力学原理进行实际和创新的应用。随着我们继续探索这些系统的复杂性，新的发现和进展的潜力仍然巨大，突显了热力学原理在理论和应用背景中的重要性。