graphitize

简明释义

英[ˈɡræfɪˌtaɪz]美[ˈɡræfəˌtaɪz]

v. 使石墨化

第 三 人 称 单 数 g r a p h i t i z e s

现 在 分 词 g r a p h i t i z i n g

过 去 式 g r a p h i t i z e d

过 去 分 词 g r a p h i t i z e d

英英释义

单词用法

同义词

反义词

例句

1.In the process of recycling, we need to graphitize the carbon materials to enhance their conductivity.

在回收过程中，我们需要石墨化碳材料以提高其导电性。

2.Researchers aim to graphitize organic precursors to create high-performance electrodes for batteries.

研究人员旨在石墨化有机前体，以制造高性能电池电极。

3.To improve the thermal properties of the material, scientists decided to graphitize it through heat treatment.

为了改善材料的热性能，科学家决定通过热处理来石墨化它。

4.The new method allows us to graphitize biomass efficiently, making it suitable for energy applications.

这种新方法使我们能够高效地石墨化生物质，使其适用于能源应用。

5.To achieve better electrical conductivity, they had to graphitize the composite material.

为了获得更好的电导率，他们必须对复合材料进行石墨化。

作文

The process of carbon transformation into a graphitic form is known as graphitize. This term is particularly significant in the fields of material science and engineering, where understanding the structure and properties of materials is crucial. When we talk about graphitize, we are often referring to the methods used to convert carbon-based materials into graphite, which is a highly stable form of carbon with unique properties. Graphite is widely used in various applications, such as batteries, lubricants, and even in the production of steel. The ability to graphitize carbon materials enhances their performance and longevity. For instance, in the manufacturing of electrodes for lithium-ion batteries, the process of graphitize allows for better conductivity, which is essential for efficient energy storage and transfer. The graphitize process typically involves heating carbon-rich materials to high temperatures, usually exceeding 2000 degrees Celsius, in an inert atmosphere. This heat treatment promotes the reorganization of carbon atoms into a layered, hexagonal structure characteristic of graphite. As a result, the physical and chemical properties of the material change significantly. The newly formed graphite exhibits increased electrical conductivity, thermal stability, and resistance to chemical corrosion. Moreover, the importance of graphitize extends beyond industrial applications. In the realm of geology, the natural occurrence of graphite can be observed in metamorphic rocks, where organic carbon undergoes geological processes over millions of years. Understanding how carbon can graphitize naturally helps scientists unravel the history of carbon cycles on Earth and the formation of natural resources. In recent years, researchers have been exploring innovative ways to graphitize alternative carbon sources, such as biomass and waste materials. By transforming these materials into graphite, we can not only create valuable products but also contribute to sustainable practices by reducing waste. This approach aligns with the global push towards a circular economy, where resources are reused and repurposed rather than discarded. In conclusion, the term graphitize encapsulates a critical process in both material science and environmental sustainability. Whether through the enhancement of industrial materials or the exploration of natural geological processes, the ability to graphitize carbon is pivotal in advancing technology and promoting ecological balance. As we continue to innovate and discover new applications for graphite, the significance of graphitize will undoubtedly grow, shaping the future of materials science and environmental stewardship.

将碳转化为石墨形式的过程称为graphitize。这个术语在材料科学和工程领域尤为重要，因为理解材料的结构和特性至关重要。当我们谈论graphitize时，通常指的是将以碳为基础的材料转化为石墨的方法，石墨是一种具有独特特性的高度稳定的碳形式。 石墨广泛应用于各种领域，如电池、润滑剂，甚至钢铁生产。能够graphitize碳材料增强了它们的性能和耐用性。例如，在锂离子电池电极的制造中，graphitize过程可以提高导电性，这对高效的能量存储和传输至关重要。 graphitize过程通常涉及将富含碳的材料加热到高温，通常超过2000摄氏度，在惰性气氛中进行。这种热处理促进了碳原子的重组，形成石墨特有的层状六角结构。因此，材料的物理和化学性质发生显著变化。新形成的石墨表现出更高的电导率、热稳定性和化学腐蚀抵抗力。 此外，graphitize的重要性超出了工业应用。在地质学领域，石墨的自然存在可以在变质岩中观察到，其中有机碳经过数百万年的地质过程。理解碳如何自然地graphitize有助于科学家揭示地球碳循环的历史及自然资源的形成。 近年来，研究人员一直在探索创新的方法，将替代碳源（如生物质和废弃物）graphitize。通过将这些材料转化为石墨，我们不仅可以创造有价值的产品，还可以通过减少废物来促进可持续实践。这种方法与全球推动循环经济的目标一致，在循环经济中，资源被重复使用和再利用，而不是被丢弃。 总之，术语graphitize概括了材料科学和环境可持续性中的一个关键过程。无论是通过增强工业材料还是探索自然地质过程，能够graphitize碳在推动技术进步和促进生态平衡方面都是至关重要的。随着我们继续创新和发现石墨的新应用，graphitize的重要性无疑会增长，塑造材料科学和环境管理的未来。