multilayer ceramic

简明释义

多层陶瓷

英英释义

例句

1.Researchers are exploring the thermal properties of multilayer ceramic materials for aerospace applications.

研究人员正在探索多层陶瓷材料在航空航天应用中的热性能。

2.The dental industry often uses multilayer ceramic for creating natural-looking dental restorations.

牙科行业常常使用多层陶瓷制作自然外观的牙齿修复体。

3.The new smartphone features a case made from multilayer ceramic, which provides enhanced durability.

这款新智能手机的外壳采用了多层陶瓷材料，提供了更好的耐用性。

4.The multilayer ceramic technology allows for miniaturization in various electronic devices.

多层陶瓷技术使得各种电子设备的小型化成为可能。

5.In the field of electronics, multilayer ceramic capacitors are widely used due to their high capacitance.

在电子领域，多层陶瓷电容器因其高电容值而被广泛使用。

作文

The field of materials science has witnessed remarkable advancements over the years, particularly in the development and application of various materials. One such material that has garnered significant attention is multilayer ceramic (多层陶瓷). This innovative material is composed of multiple layers of ceramic that are stacked together, providing unique properties that make it suitable for a wide range of applications. In this essay, I will explore the characteristics, advantages, and applications of multilayer ceramic in modern technology.Firstly, the structure of multilayer ceramic is one of its defining features. The layering process involves the careful arrangement of different ceramic materials, which can vary in composition and thickness. This multilayer configuration allows for enhanced mechanical strength and improved thermal stability compared to single-layer ceramics. The ability to tailor the properties of each layer enables engineers to design ceramics that meet specific performance requirements, making multilayer ceramic an attractive option in industries that demand high-performance materials.One of the key advantages of multilayer ceramic is its excellent dielectric properties. This makes it highly suitable for electronic applications, particularly in capacitors and insulators. The multilayer structure can significantly reduce the size of these components while maintaining their efficiency. As the demand for smaller and more efficient electronic devices continues to grow, the role of multilayer ceramic in the electronics industry becomes increasingly important.In addition to its electronic applications, multilayer ceramic is also utilized in the field of energy storage and conversion. For instance, solid oxide fuel cells (SOFCs) benefit from the use of multilayer ceramics, as they can withstand high temperatures and provide excellent ionic conductivity. This characteristic is essential for the efficient operation of fuel cells, which are considered a promising technology for clean energy production.Moreover, the versatility of multilayer ceramic extends to the biomedical field as well. Researchers have been exploring its potential for use in implants and prosthetics due to its biocompatibility and mechanical strength. The ability to create customized multilayer structures allows for the development of implants that can better integrate with human tissue, thereby improving patient outcomes.Despite its many advantages, the production of multilayer ceramic can be complex and costly. The manufacturing process often requires advanced techniques, such as tape casting or co-firing, to ensure that the layers adhere properly and maintain their desired properties. However, ongoing research and technological advancements aim to streamline these processes, making multilayer ceramic more accessible for widespread use.In conclusion, multilayer ceramic (多层陶瓷) represents a significant advancement in materials science, offering unique properties that cater to a variety of applications across different industries. Its exceptional mechanical strength, dielectric properties, and versatility make it an invaluable material in electronics, energy systems, and biomedical applications. As research continues to evolve and manufacturing techniques improve, the potential for multilayer ceramic to revolutionize various fields remains promising. The future of this material is bright, and its impact on technology and society is likely to grow in the coming years.

材料科学领域近年来见证了显著的进步，尤其是在各种材料的开发和应用方面。其中一种受到广泛关注的材料是多层陶瓷（multilayer ceramic）。这种创新材料由多层陶瓷叠加而成，提供了独特的性能，使其适用于广泛的应用。在这篇文章中，我将探讨多层陶瓷的特性、优势和在现代技术中的应用。首先，多层陶瓷的结构是其定义特征之一。分层过程涉及不同陶瓷材料的精心排列，这些材料可以在成分和厚度上有所不同。这种多层配置允许比单层陶瓷更高的机械强度和更好的热稳定性。每一层性能的定制能力使工程师能够设计出符合特定性能要求的陶瓷，使多层陶瓷成为要求高性能材料的行业的理想选择。多层陶瓷的一个关键优势是其优异的介电性能。这使其非常适合电子应用，尤其是在电容器和绝缘体中。多层结构可以显著减小这些组件的尺寸，同时保持其效率。随着对更小、更高效的电子设备需求的不断增长，多层陶瓷在电子行业中的作用变得越来越重要。除了电子应用外，多层陶瓷还被用于能源存储和转换领域。例如，固体氧化物燃料电池（SOFC）受益于多层陶瓷的使用，因为它们能够承受高温并提供优良的离子导电性。这一特性对燃料电池的高效运行至关重要，而燃料电池被视为清洁能源生产的有前景的技术。此外，多层陶瓷的多功能性还扩展到生物医学领域。研究人员一直在探索其在植入物和假肢中的潜力，因为其具有生物相容性和机械强度。定制多层结构的能力使得开发出更好地与人体组织整合的植入物成为可能，从而改善患者的治疗效果。尽管有许多优势，多层陶瓷的生产可能复杂且成本较高。制造过程通常需要先进的技术，如带材铸造或共烧，以确保各层正确粘附并保持所需的性能。然而，持续的研究和技术进步旨在简化这些过程，使多层陶瓷更容易获得以实现广泛应用。总之，多层陶瓷（multilayer ceramic）代表了材料科学的重要进步，提供了独特的性能，满足不同行业各种应用的需求。其卓越的机械强度、介电性能和多功能性，使其在电子、能源系统和生物医学应用中成为无价的材料。随着研究的不断发展和制造技术的改善，多层陶瓷在各个领域革命化的潜力依然令人期待。这种材料的未来光明，其对技术和社会的影响在未来几年可能会不断增长。