cryogenic element

简明释义

低温元件

英英释义

例句

1.During the experiment, we monitored the behavior of the cryogenic element (低温元件) under extreme conditions.

在实验期间，我们监测了cryogenic element (低温元件) 在极端条件下的行为。

2.In the lab, we need to ensure that the cryogenic element (低温元件) is stored at the correct temperature to prevent degradation.

在实验室中，我们需要确保cryogenic element (低温元件) 在正确的温度下存储，以防止降解。

3.The cryogenic element (低温元件) plays a crucial role in superconducting materials, allowing them to conduct electricity without resistance.

在超导材料中，cryogenic element (低温元件) 起着至关重要的作用，使它们能够无阻力地导电。

4.The research team is developing a new type of rocket engine that utilizes a cryogenic element (低温元件) to improve efficiency.

研究团队正在开发一种新型火箭发动机，利用cryogenic element (低温元件) 来提高效率。

5.Engineers must consider the thermal properties of the cryogenic element (低温元件) when designing storage tanks.

工程师在设计储罐时必须考虑cryogenic element (低温元件) 的热特性。

作文

In the realm of science and technology, the study of materials at extremely low temperatures has become increasingly significant. One of the most fascinating aspects of this field is the behavior of various substances when subjected to cryogenic conditions. A key term that often arises in this context is the cryogenic element, which refers to any material that exhibits unique properties when cooled to cryogenic temperatures. These temperatures are typically below -150 degrees Celsius (-238 degrees Fahrenheit), where many elements and compounds behave differently than they do at room temperature.Understanding cryogenic elements is crucial for numerous applications across various industries. For instance, in the aerospace sector, cryogenic elements are used as fuels for rockets. Liquid oxygen and liquid hydrogen, both of which are considered cryogenic elements, play a vital role in propelling spacecraft into orbit. The efficiency of these fuels is largely due to their ability to store a large amount of energy in a small volume, which is essential for space missions.Moreover, the medical field also benefits from cryogenic elements. In cryopreservation, biological samples such as cells, tissues, and even organs are preserved at cryogenic temperatures. This process allows for long-term storage without damaging the cellular structure, making it possible to transport and use these samples for research or transplantation purposes. The significance of cryogenic elements in medicine cannot be overstated, as it opens up new avenues for treatment and research.Furthermore, the study of cryogenic elements extends to physics, particularly in the field of superconductivity. Superconductors are materials that can conduct electricity with zero resistance when cooled to cryogenic temperatures. This phenomenon has led to advancements in magnetic levitation and lossless power transmission, demonstrating the practical applications of cryogenic elements in modern technology.However, working with cryogenic elements also poses challenges. The extreme temperatures required to achieve cryogenic states necessitate specialized equipment and safety protocols to handle these materials safely. Researchers and engineers must be trained to work with liquid gases and insulated containers to prevent accidents and ensure reliable results.In conclusion, the concept of cryogenic elements encompasses a wide range of materials that exhibit remarkable properties at low temperatures. From aerospace engineering to medical applications and advancements in physics, the importance of understanding cryogenic elements cannot be overlooked. As technology continues to evolve, the exploration of these materials will undoubtedly lead to further innovations and discoveries that can benefit society as a whole.

在科学和技术领域，研究材料在极低温度下的行为变得越来越重要。这个领域中一个最引人入胜的方面是各种物质在经历低温条件时的表现。在这种背景下，一个关键术语是低温元素，它指的是任何在冷却到低温时展示独特性质的材料。这些温度通常低于-150摄氏度（-238华氏度），在这个温度下，许多元素和化合物的行为与室温下大相径庭。理解低温元素对于多个行业中的众多应用至关重要。例如，在航空航天领域，低温元素被用作火箭燃料。液氧和液氢，都是被认为是低温元素，在推动航天器进入轨道方面发挥着至关重要的作用。这些燃料的效率主要归因于它们能够在小体积中储存大量能量，这对于太空任务至关重要。此外，医学领域也受益于低温元素。在低温保存中，生物样本如细胞、组织甚至器官在低温下被保存。这个过程使得这些样本可以长期储存而不损坏细胞结构，从而使得可以运输和使用这些样本进行研究或移植。低温元素在医学中的重要性不容小觑，因为它为治疗和研究开辟了新的途径。此外，低温元素的研究还延伸到物理学，特别是在超导性领域。超导体是指在低温下可以无电阻地导电的材料。这一现象导致了磁悬浮和无损电力传输的进步，展示了低温元素在现代技术中的实际应用。然而，处理低温元素也面临挑战。达到低温所需的极端温度需要专门的设备和安全协议，以安全地处理这些材料。研究人员和工程师必须接受培训，以安全地操作液体气体和绝缘容器，以防止事故并确保可靠的结果。总之，低温元素的概念涵盖了一系列在低温下表现出显著性质的材料。从航空航天工程到医学应用以及物理学的进展，理解低温元素的重要性不容忽视。随着技术的不断发展，对这些材料的探索无疑将导致进一步的创新和发现，造福整个社会。