graphitized

简明释义

英[ˈɡræfɪtaɪzd]美[ˈɡræfɪtaɪzd]

v. 石墨化（graphitize 的过去分词）

adj. 石墨化的

英英释义

单词用法

同义词

反义词

例句

1.The graphitized waste and scrap auxiliary materials produced in the process of carbon production are solid waste but have great potentiality for recovery.

炭素石墨制品生产过程中产生的石墨化废旧辅料，在炭素行业是最有开发潜力的固体废物。

2.The graphitized waste and scrap auxiliary materials produced in the process of carbon production are solid waste but have great potentiality for recovery.

炭素石墨制品生产过程中产生的石墨化废旧辅料，在炭素行业是最有开发潜力的固体废物。

3.Polyacrylonitrile carbon fiber (PAN-CF) was tension carbonized at different temperatures and then graphitized.

在不同温度下对聚丙烯腈基炭纤维(PAN CF)进行张力炭化处理并进行高温石墨化。

4.The microstructures of graphitized carbon varies with increasing temperature.

当石墨化碳被加热到不同温度时，其微结构也不同。

5.The invention belongs to a graphitized cathode production technique.

本发明属于石墨化阴极生产技术。

6.The steel was treated to make it more durable, resulting in a graphitized 石墨化的 finish.

这钢材经过处理，使其更加耐用，最终呈现出一种石墨化的外观。

7.In the production of batteries, graphitized 石墨化的 materials are essential for improving conductivity.

在电池生产中，石墨化的材料对提高导电性至关重要。

8.The researchers discovered that graphitized 石墨化的 carbon could enhance the performance of solar cells.

研究人员发现，石墨化的碳可以提高太阳能电池的性能。

9.During the experiment, they used a graphitized 石墨化的 electrode to measure the electrical resistance accurately.

在实验过程中，他们使用了一个石墨化的电极来准确测量电阻。

10.The graphitized 石墨化的 powder is often used in lubricants due to its low friction properties.

这种石墨化的粉末常用于润滑剂，因为它具有低摩擦特性。

作文

In the field of materials science, the term graphitized refers to the process of converting carbon-based materials into graphite. This transformation is crucial because graphite possesses unique properties that make it highly valuable in various industrial applications. The graphitized material exhibits excellent electrical conductivity, high thermal resistance, and remarkable lubricating capabilities. These attributes are essential in industries such as electronics, metallurgy, and even in the production of batteries. The process of graphitized typically involves heating carbon-rich materials to elevated temperatures in an inert atmosphere. During this process, the carbon atoms rearrange themselves into a crystalline structure that characterizes graphite. This transformation not only enhances the physical properties of the material but also increases its stability and longevity. For example, when coal or petroleum coke is graphitized, it can be used to create electrodes for electric arc furnaces, which are vital in steel production. Moreover, the graphitized form of carbon is also significant in the realm of energy storage. Lithium-ion batteries, which power many of our modern devices, utilize graphitized carbon as an anode material. The ability of graphitized carbon to intercalate lithium ions allows for efficient charge and discharge cycles, leading to improved battery performance and longevity. As the demand for energy-efficient technologies grows, the role of graphitized materials becomes increasingly important. In addition to its industrial applications, graphitized carbon has found its way into everyday products. For instance, the pencils we use in schools often contain a mixture of clay and graphitized carbon. The varying ratios of these materials determine the hardness and darkness of the pencil lead. This simple yet effective use of graphitized carbon showcases its versatility and importance in daily life. Furthermore, research continues to explore new ways to utilize graphitized materials. Scientists are investigating their potential in fields such as nanotechnology and environmental remediation. For example, graphitized carbon nanotubes are being studied for their strength and lightweight properties, making them ideal candidates for advanced composite materials. Additionally, graphitized carbon can be employed in water purification systems due to its adsorptive capabilities, helping to remove contaminants from drinking water. In conclusion, the term graphitized encapsulates a transformative process that enhances the properties of carbon-based materials, making them suitable for a wide range of applications. From industrial uses in steel production to everyday items like pencils, the significance of graphitized carbon cannot be overstated. As technology advances and the demand for innovative materials grows, the importance of understanding and utilizing graphitized substances will only increase, paving the way for future developments that harness their unique characteristics.

在材料科学领域，术语graphitized指的是将碳基材料转化为石墨的过程。这种转变至关重要，因为石墨具有独特的性质，使其在各种工业应用中极具价值。graphitized材料表现出优良的电导率、高热阻和显著的润滑能力。这些特性在电子、冶金乃至电池生产等行业中都是必不可少的。 graphitized的过程通常涉及在惰性气氛中将富含碳的材料加热到高温。在此过程中，碳原子重新排列成石墨的晶体结构。这种转变不仅增强了材料的物理性能，还提高了其稳定性和耐久性。例如，当煤或石油焦被graphitized时，可以用来制造电弧炉的电极，这在钢铁生产中至关重要。 此外，graphitized形式的碳在能源存储领域也具有重要意义。锂离子电池为我们现代设备提供动力，利用graphitized碳作为阳极材料。graphitized碳能够插层锂离子的能力使得充放电循环高效，从而提高电池的性能和使用寿命。随着对节能技术需求的增长，graphitized材料的作用变得愈发重要。 除了工业应用，graphitized碳还进入了日常产品。例如，我们在学校使用的铅笔通常含有粘土和graphitized碳的混合物。这些材料的不同比例决定了铅笔芯的硬度和深度。这种简单而有效的graphitized碳的使用展示了它的多功能性和在日常生活中的重要性。 此外，研究仍在继续探索利用graphitized材料的新方法。科学家们正在研究它们在纳米技术和环境修复等领域的潜力。例如，graphitized碳纳米管因其强度和轻量特性而受到关注，使其成为先进复合材料的理想候选者。此外，graphitized碳可以用于水净化系统，凭借其吸附能力帮助去除饮用水中的污染物。 总之，术语graphitized概括了一种转化过程，该过程增强了碳基材料的属性，使其适合广泛的应用。从钢铁生产中的工业用途到铅笔等日常用品，graphitized碳的重要性不容小觑。随着技术的发展和对创新材料需求的增长，理解和利用graphitized物质的重要性只会增加，为未来开发利用其独特特性铺平道路。