graphitizing

简明释义

英[ˈɡræfɪtaɪzɪŋ]美[ˈɡræfɪtaɪzɪŋ]

n. [化工][冶]石墨化；石墨化作用

v. 使……石墨化（graphitize 的 ing 形式）

英英释义

单词用法

同义词

反义词

例句

1.The resistance furnace can be heated to very high temperatures, the supplies graphitizing furnace carbon materials, for example, can put the material heated to a temperature of more than 2500.

这种电阻炉可以把物料加热到很高的温度，例如碳素材料石墨化电炉，能把物料加热到超过2500。

2.The resistance furnace can be heated to very high temperatures, the supplies graphitizing furnace carbon materials, for example, can put the material heated to a temperature of more than 2500.

这种电阻炉可以把物料加热到很高的温度，例如碳素材料石墨化电炉，能把物料加热到超过2500。

3.Solidification process of CV graphite iron with the addition of various CV-graphitizing materials and the crystallization behavior of the graphite during the eutectic reaction was clarified.

通过对各种处理剂处理的蠕虫状石墨铸铁凝固过程的研究，共晶反应时石墨的析出过程已经明确。

4.All graphitizing elements decrease the metastable eutectic temperature, increase the stable eutectic temperature and enlarge their distance.

所有石墨化元素均降低介稳定共晶温度，而提高稳定共晶温度，并使两者间距扩大。

5.The effect of the rare earth compound inoculant on graphitizing the annealing period of the malleable cast-iron was studied and analyzed.

配制了以稀土元素为主的可锻铸铁复合孕育剂，进行了生产实验，研究和分析了稀土复合孕育剂对可锻铸铁石墨化退火周期的影响。

6.The influence of SG inoculant on graphitizing annealing of malleable cast iron was investigated.

研究了SG变质剂对可锻铸铁石墨化退火的影响。

7.The measuring temperature for graphitizing furnace was studied.

对石墨化电炉的测温进行了探索。

8.The process of graphitizing involves heating carbon materials to convert them into graphite.

石墨化的过程涉及加热碳材料以将其转化为石墨。

9.In metallurgy, graphitizing is crucial for enhancing the properties of cast iron.

石墨化在冶金中对于提升铸铁的性能至关重要。

10.Researchers are studying the effects of graphitizing on the conductivity of carbon composites.

研究人员正在研究石墨化对碳复合材料导电性的影响。

11.The graphitizing treatment can significantly improve the thermal stability of carbon fibers.

石墨化处理可以显著提高碳纤维的热稳定性。

12.During the graphitizing process, impurities are often removed to enhance material purity.

在石墨化过程中，通常会去除杂质以提高材料的纯度。

作文

In the world of materials science, the process of graphitizing (石墨化) plays a crucial role in enhancing the properties of various carbon-based materials. This transformation involves converting amorphous carbon into graphite, which is characterized by its layered structure and excellent electrical conductivity. The significance of graphitizing (石墨化) cannot be overstated, as it directly impacts the performance of materials used in numerous applications, from batteries to electrodes in electrochemical cells. The process of graphitizing (石墨化) typically occurs at high temperatures, usually above 2500 degrees Celsius. During this phase, the carbon atoms rearrange themselves into a hexagonal lattice structure, which is a defining feature of graphite. This structural change not only improves the electrical conductivity of the material but also enhances its thermal stability and mechanical strength. As a result, materials that undergo graphitizing (石墨化) are often used in applications that require high performance under extreme conditions. One of the most notable applications of graphitizing (石墨化) is in the production of anodes for lithium-ion batteries. The demand for efficient energy storage solutions has skyrocketed in recent years, and materials that have undergone graphitizing (石墨化) are favored due to their superior conductivity and capacity to intercalate lithium ions. This means that batteries made with graphitized materials can charge faster and store more energy, making them ideal for use in electric vehicles and portable electronics. Moreover, graphitizing (石墨化) is also essential in the manufacturing of high-performance electrodes for various electrochemical processes. In fuel cells, for instance, the efficiency of the reaction can be significantly improved by using graphitized carbon materials. The enhanced surface area and conductivity provided by graphitizing (石墨化) allow for better electron transfer, leading to higher overall efficiency of the cell. In addition to its industrial applications, the study of graphitizing (石墨化) provides insights into the fundamental behavior of carbon materials. Researchers are continually exploring the nuances of this process to develop new materials with tailored properties. For example, by controlling the conditions under which graphitizing (石墨化) occurs, scientists can create materials with specific electrical, thermal, or mechanical characteristics, opening up new avenues for innovation in material design. Despite the benefits of graphitizing (石墨化), there are challenges associated with the process. Achieving uniformity in the graphitization of large-scale materials can be difficult, and variations in temperature or pressure can lead to inconsistencies in the final product. Additionally, the environmental impact of high-temperature processing is a concern, prompting researchers to seek more sustainable methods of achieving graphitization. In conclusion, the process of graphitizing (石墨化) is a vital aspect of materials science that significantly enhances the properties of carbon-based materials. Its applications in energy storage and electrochemical systems highlight its importance in modern technology. As research continues to advance, the understanding and control of graphitizing (石墨化) will likely lead to even more innovative materials, paving the way for future technological advancements.