graphitic

简明释义

英[ɡrəˈfɪtɪk]美[ɡrəˈfɪtɪk]

adj. 石墨的

英英释义

单词用法

同义词

反义词

例句

1.The ingot mold made of vanadium titanium vermicular graphitic cast iron has the best comprehensive property.

钒钛蠕墨铸铁是一种新型的工程结构材料，用钒钛蠕铁制造钢锭模具有良好的综合性能。

2.Several morphological ballas structures have been observed by varying the deposition conditions, i. e. ballas having faceted areas, flat ballas, ballas with graphitic inclusions, etc.

通过改变沉积条件，发现了几种形貌的半刚石结构，即具有多面的半刚石、平整的半刚石和含石墨杂质的半刚石等等。

3.These lamella appear to be of graphitic nature since Raman spectra show a sharp graphite peak at about 1585 cm-1 when lamellae are present.

这些薄层好象具有石墨性质，因为当薄层出现时，拉曼光谱在大约1585cm - 1处显示出一个锐利的石墨峰。

4.Graphitic particle furnace which is a general furnace in usual can be served as carbonizing by adding a litter catalyst, without any assistant devices on carbonizing temperature.

平时作为加热炉使用的石墨流态粒子炉，在无需添加任何辅助装置、只需在石墨粒子中加入极少量的催化剂在渗碳温度下即可实现渗碳。

5.Process of hydrogen chloride synthesed by two-in-one graphitic synthetic furnace and its specification of equipment were briefly introduced. Operational status was analysed.

简要介绍了二合一石墨合成炉合成氯化氢的工艺流程及设备规格，并对运行情况进行了总结分析。

6.Several morphological ballas structures have been observed by varying the deposition conditions, i. e. ballas having faceted areas, flat ballas, ballas with graphitic inclusions, etc.

通过改变沉积条件，发现了几种形貌的半刚石结构，即具有多面的半刚石、平整的半刚石和含石墨杂质的半刚石等等。

7.The new batteries utilize a graphitic material to enhance their conductivity.

新电池使用一种石墨的材料来增强其导电性。

8.Researchers discovered that adding graphitic nanoparticles improved the strength of the composite.

研究人员发现，添加石墨的纳米颗粒提高了复合材料的强度。

9.The lubricating oil contains graphitic additives for better performance under high pressure.

润滑油中含有石墨的添加剂，以在高压下提供更好的性能。

10.In geology, graphitic schist is a common metamorphic rock found in many mountain ranges.

在地质学中，石墨的片岩是许多山脉中常见的变质岩。

11.The graphitic structure of the material allows it to conduct electricity efficiently.

该材料的石墨的结构使其能够有效地导电。

作文

The term graphitic refers to the properties or characteristics associated with graphite, a form of carbon that is known for its unique structure and remarkable qualities. Graphite is composed of layers of carbon atoms arranged in a hexagonal lattice, which gives it its distinct properties such as lubricity, electrical conductivity, and thermal resistance. These attributes make graphite an invaluable material in various industries, ranging from electronics to metallurgy. Understanding the graphitic nature of materials can lead to innovative applications and advancements in technology. In recent years, there has been a growing interest in the use of graphitic materials in the field of energy storage. For instance, lithium-ion batteries, which are widely used in portable electronics and electric vehicles, often utilize graphitic carbon as the anode material. The layered structure of graphite allows lithium ions to intercalate between the layers, facilitating efficient charge and discharge cycles. This has made graphitic materials essential for enhancing battery performance and longevity. Moreover, the graphitic properties of certain materials have also led to advancements in the production of supercapacitors. Supercapacitors are energy storage devices that offer rapid charge and discharge capabilities, making them ideal for applications requiring quick bursts of energy. By incorporating graphitic structures into their design, researchers have been able to improve the energy density and efficiency of these devices, paving the way for more sustainable energy solutions. Beyond energy storage, the graphitic nature of materials plays a critical role in the development of lubricants. Traditional lubricants can degrade under high temperatures and pressures, leading to increased friction and wear in machinery. However, graphitic lubricants exhibit excellent thermal stability and can withstand extreme conditions. Their layered structure allows them to slide easily over one another, significantly reducing friction and wear. This property is particularly beneficial in automotive and industrial applications, where maintaining optimal performance is crucial. Furthermore, the graphitic nature of certain materials has implications in the field of electronics. Conductive inks made from graphitic materials are being explored for use in flexible electronics, printed circuit boards, and sensors. These inks can be applied to various substrates, enabling the creation of lightweight and bendable electronic devices. As the demand for portable and flexible technology continues to rise, the significance of graphitic materials in electronics will only increase. In conclusion, the term graphitic encompasses a wide range of applications and implications across various industries. From energy storage to lubrication and electronics, the unique properties of graphitic materials are driving innovation and enhancing performance. As research progresses and new technologies emerge, understanding the graphitic nature of materials will be essential for developing sustainable solutions and advancing modern technology. The future holds great promise for graphitic materials, and their role in shaping our technological landscape cannot be underestimated.

术语graphitic指的是与石墨相关的特性或特征，石墨是一种碳的形式，以其独特的结构和显著的特性而闻名。石墨由以六角形晶格排列的碳原子层组成，这赋予它润滑性、电导性和热阻等独特的属性。这些特性使石墨在从电子到冶金的各个行业中成为一种宝贵的材料。理解材料的graphitic性质可以带来创新的应用和技术的进步。 近年来，graphitic材料在能源存储领域受到了越来越多的关注。例如，锂离子电池广泛用于便携式电子设备和电动汽车，通常利用graphitic碳作为阳极材料。石墨的层状结构允许锂离子在层间插层，从而促进高效的充放电循环。这使得graphitic材料对于提高电池性能和寿命至关重要。 此外，某些材料的graphitic特性也推动了超级电容器的生产。超级电容器是能量存储设备，提供快速充放电能力，使其非常适合需要快速能量爆发的应用。通过将graphitic结构纳入设计，研究人员能够提高这些设备的能量密度和效率，为更可持续的能源解决方案铺平道路。 除了能源存储，某些材料的graphitic性质在润滑剂的发展中也发挥着关键作用。传统润滑剂在高温和高压下可能会降解，导致机械摩擦和磨损增加。然而，graphitic润滑剂表现出优异的热稳定性，能够承受极端条件。它们的层状结构使它们能够相互滑动，从而显著减少摩擦和磨损。这一特性在汽车和工业应用中尤为有利，在这些领域，保持最佳性能至关重要。 此外，某些材料的graphitic性质在电子领域也具有重要意义。由graphitic材料制成的导电墨水正被探索用于柔性电子产品、印刷电路板和传感器。这些墨水可以应用于各种基材，使得轻便和可弯曲的电子设备得以制造。随着对便携式和柔性技术需求的不断上升，graphitic材料在电子产品中的重要性只会增加。 总之，术语graphitic涵盖了各个行业中广泛的应用和影响。从能源存储到润滑和电子产品，graphitic材料的独特属性正在推动创新并提升性能。随着研究的进展和新技术的出现，理解材料的graphitic性质对于开发可持续解决方案和推动现代技术至关重要。未来对graphitic材料充满希望，它们在塑造我们技术格局中的角色不可低估。