niobate

简明释义

英[ˈnaɪəʊbeɪt]美[ˈnaɪəbeɪt]

n. [无化] 铌酸盐

英英释义

单词用法

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例句

1.The topography of crystal grain of potassium niobate was also analyzed by SEM.

并通过SEM分析了铌酸钾的晶粒形貌。

2.Novel relaxor ferroelectric single crystal lead magnesium niobate-lead titanate (PMNT) has been found to exhibit excellent piezoelectric properties near the morphotropic phase boundary (MPB).

新型弛豫铁电单晶铌镁酸铅—钛酸铅(PMNT)在准同型相界(MPB)附近具有非常优异的压电性能。

3.Project Director, Research Project "Origin of light-induced scattering in lithium niobate doubly doped with Fe and Hf", National Natural Science Foundation.

主持国家自然科学基金项目“铁铪双掺铌酸锂晶体的光散射起源研究”。

4.Up to date, the doped lithium niobate crystal is the most ideal three dimensional storage materi...

搀杂铌酸锂晶体是目前最理想的三维光折变存储材料。

5.We demonstrate a quasi-periodic structure exhibiting multiple photonic band gaps (PBGs) based on sub-micron-period poled lithium niobate (LN).

我们在本文中提出了基于亚微米准周期极化铌酸锂实现多波长光子禁带的结构。

6.Strontium sodium lithium niobate (SNLN) single crystal possesses good electro-optical properties, but at room temperature only its metastable phase can be obtained.

铌酸锶钠锂单晶具有优良的电光性能，但它在室温下为亚稳相。

7.Nano-sized silver sodium niobate tantalate was studied in this paper using wet-chemical method.

对液相法合成钽铌酸银钠的纳米粉体进行了研究。

8.Project Director, Research Project "Effect of spatial distribution of intrinsic defects on poling field of lithium niobate crystals", The Education Department of Hebei Province.

主持河北省教育厅项目“本征缺陷的空间分布对铌酸锂畴反转电场的影响研究”。

9.The present invention relates to lead-less piezoelectric ceramic composition and is especially one kind of lead-less Li-Na-K niobate piezoelectric ceramic and its preparation process.

一种高居里点铌酸钾钠锂系无铅压电陶瓷及其制备工艺，涉及一种性能优良的无铅压 电陶瓷组合物的配方及制备工艺。

10.The researchers synthesized a new compound using niobate for better electronic properties.

研究人员合成了一种新化合物，使用铌酸盐以获得更好的电子特性。

11.In piezoelectric applications, niobate materials are often preferred due to their high sensitivity.

在压电应用中，铌酸盐材料因其高灵敏度而被广泛使用。

12.The team explored the thermal stability of niobate ceramics in harsh environments.

团队研究了铌酸盐陶瓷在恶劣环境中的热稳定性。

13.Using niobate crystals can enhance the performance of optical devices.

使用铌酸盐晶体可以提升光学设备的性能。

14.The electrical characteristics of niobate thin films were analyzed in the study.

研究中分析了铌酸盐薄膜的电气特性。

作文

Niobate, a compound derived from niobium, is increasingly recognized for its unique properties and applications in various fields of science and technology. This fascinating material is often found in the form of niobate crystals or ceramics, which exhibit remarkable electrical and optical characteristics. The significance of niobate (铌酸盐) lies not only in its inherent properties but also in its versatility for use in modern electronic devices. In recent years, the demand for advanced materials has surged due to the rapid development of technology. Niobate (铌酸盐) compounds, particularly lithium niobate, have emerged as critical components in the production of optical waveguides, frequency converters, and electro-optic devices. These applications are vital in telecommunications, where efficient signal processing is essential. The ability of niobate (铌酸盐) to modulate light makes it an ideal candidate for developing high-speed communication systems. Moreover, niobate (铌酸盐) is known for its piezoelectric properties, allowing it to generate an electric charge in response to mechanical stress. This characteristic is harnessed in various sensors and actuators, contributing to advancements in robotics and automation. The integration of niobate (铌酸盐) materials into these technologies enhances their performance and reliability, paving the way for smarter and more efficient systems. The exploration of niobate (铌酸盐) in energy applications is another promising avenue. Researchers are investigating its potential in solid-state batteries, where its unique ionic conductivity could lead to higher efficiency and longer-lasting energy storage solutions. As the world shifts towards sustainable energy sources, materials like niobate (铌酸盐) could play a pivotal role in the development of next-generation energy systems. Furthermore, the synthesis of niobate (铌酸盐) materials has evolved significantly, with advances in nanotechnology enabling the production of nanoscale niobate structures. These nanostructures exhibit enhanced properties compared to their bulk counterparts, leading to innovative applications in nanophotonics and quantum computing. The ability to manipulate light at the nanoscale using niobate (铌酸盐) could revolutionize information processing and storage technologies. Despite its promising attributes, the production and application of niobate (铌酸盐) also pose challenges. The extraction of niobium, primarily sourced from mineral deposits, raises environmental concerns. Sustainable practices in mining and material processing are crucial to minimize ecological impact. Moreover, the cost associated with high-purity niobate (铌酸盐) materials can be a barrier to widespread adoption in commercial applications. In conclusion, niobate (铌酸盐) represents a class of materials with exceptional properties that have far-reaching implications across various technological domains. Its role in telecommunications, energy storage, and advanced manufacturing highlights the importance of continued research and innovation in this field. As we navigate the challenges associated with its production and application, the future of niobate (铌酸盐) looks promising, with the potential to significantly impact our technological landscape in the years to come.