transition temperature

简明释义

转变温度

英英释义

例句

1.Understanding the transition temperature 转变温度 is crucial for designing effective thermal insulation materials.

理解转变温度对设计有效的隔热材料至关重要。

2.The material's transition temperature 转变温度 determines its suitability for high-temperature applications.

材料的转变温度决定了其在高温应用中的适用性。

3.During the experiment, we observed that the transition temperature 转变温度 of the polymer changed with different additives.

在实验过程中，我们观察到聚合物的转变温度随着不同添加剂的变化而变化。

4.We need to measure the transition temperature 转变温度 of this alloy under various conditions.

我们需要在不同条件下测量该合金的转变温度。

5.The transition temperature 转变温度 of superconductors is a key factor in their practical applications.

超导体的转变温度是其实际应用中的关键因素。

作文

The concept of transition temperature is crucial in various fields of science, particularly in materials science and physics. It refers to the specific temperature at which a material undergoes a phase change, altering its physical properties significantly. For example, in the study of metals, the transition temperature can indicate the point at which a metal changes from a ductile state to a brittle one. This property is essential for engineers and manufacturers who need to ensure that materials can withstand certain temperatures without failing. In the realm of superconductivity, the transition temperature defines the temperature below which a material exhibits zero electrical resistance. This phenomenon has profound implications for technology, as it allows for the development of highly efficient electrical systems. Understanding the transition temperature of superconductors enables scientists to create more effective magnetic levitation systems and energy storage solutions. Moreover, the transition temperature is not limited to just metals and superconductors; it also plays a vital role in polymers. In polymer science, the transition temperature can refer to the glass transition temperature (Tg), which is the temperature range where an amorphous polymer transitions from a hard and relatively brittle state into a viscous or rubbery state. This property is crucial for determining the usability of polymers in various applications, such as packaging, automotive parts, and consumer goods.Understanding the transition temperature allows researchers and industry professionals to tailor materials for specific applications. For instance, if a particular polymer is intended for use in a high-temperature environment, knowing its transition temperature helps in selecting the right type of polymer that will maintain its integrity under those conditions. In conclusion, the transition temperature serves as a pivotal point in the study of materials and their behaviors under different thermal conditions. Its significance spans across multiple disciplines, influencing how materials are designed, tested, and utilized in real-world applications. As we continue to advance in technology and materials science, a deeper understanding of the transition temperature will undoubtedly lead to innovative solutions and improved performance in various sectors. In summary, the transition temperature (转变温度) is a fundamental concept that encompasses a wide range of scientific and engineering applications. Whether in the context of metals, superconductors, or polymers, recognizing and understanding this critical temperature helps in optimizing material selection and improving product performance. The implications of this knowledge extend beyond academia and into everyday life, highlighting the importance of interdisciplinary research in advancing our technological capabilities.

转变温度的概念在科学的各个领域中至关重要，尤其是在材料科学和物理学中。它指的是材料经历相变的特定温度，此时其物理性质会显著改变。例如，在金属研究中，转变温度可以指示金属从延展状态转变为脆性状态的点。这一特性对工程师和制造商至关重要，他们需要确保材料能够在一定温度下不发生失效。在超导现象的领域中，转变温度定义了材料表现出零电阻的温度。这一现象对技术有深远的影响，因为它允许开发高效的电力系统。了解超导体的转变温度使科学家能够创造更有效的磁悬浮系统和能量存储解决方案。此外，转变温度不仅限于金属和超导体；它在聚合物中也发挥着重要作用。在聚合物科学中，转变温度可以指玻璃转变温度（Tg），这是一个温度范围，在此范围内无定形聚合物从坚硬且相对脆弱的状态转变为粘性或橡胶状状态。这一特性对于确定聚合物在各种应用中的可用性至关重要，例如包装、汽车部件和消费品。理解转变温度使研究人员和行业专业人士能够为特定应用量身定制材料。例如，如果某种聚合物打算用于高温环境，了解其转变温度有助于选择适合该条件下保持完整性的聚合物。总之，转变温度作为研究材料及其在不同热条件下行为的关键点，其重要性跨越多个学科，影响材料的设计、测试和实际应用。随着我们在技术和材料科学上的不断进步，对转变温度的深入理解无疑将导致创新解决方案和改善各种行业的性能。总而言之，转变温度（转变温度）是一个基本概念，涵盖了广泛的科学和工程应用。无论是在金属、超导体还是聚合物的背景下，认识和理解这一关键温度有助于优化材料选择并提高产品性能。这一知识的影响超越了学术界，深入到日常生活中，突显了跨学科研究在提升我们技术能力方面的重要性。