feeroelectric n.

简明释义

铁电体 a. 铁电的

英英释义

例句

1.Researchers are exploring the use of ferroelectric n. devices in next-generation memory storage technologies.

研究人员正在探索将铁电设备应用于下一代存储技术。

2.The ferroelectric n. materials exhibit a spontaneous electric polarization that can be reversed by the application of an external electric field.

这些铁电材料表现出自发的电极化，可以通过施加外部电场来反转。

3.The piezoelectric effect observed in ferroelectric n. crystals makes them useful for sensors and actuators.

在铁电晶体中观察到的压电效应使它们在传感器和执行器中非常有用。

4.In electronics, ferroelectric n. materials can enhance the performance of capacitors.

在电子学中，铁电材料可以提高电容器的性能。

5.The study of ferroelectric n. phenomena has led to advancements in many fields, including telecommunications.

对铁电现象的研究推动了许多领域的发展，包括电信。

作文

In recent years, the field of materials science has witnessed significant advancements, particularly in the study of various properties of materials. One fascinating property that has garnered attention is that of ferroelectric n. (铁电性). This term refers to a class of materials that exhibit a spontaneous electric polarization that can be reversed by the application of an external electric field. The implications of ferroelectric n. materials are profound, with applications ranging from memory devices to sensors and actuators. The unique characteristics of ferroelectric n. materials stem from their crystal structures, which allow for the alignment of electric dipoles. This alignment results in a permanent electric polarization even in the absence of an external electric field. When an external electric field is applied, the polarization can be switched, allowing for the storage and manipulation of information. This ability to switch polarization makes ferroelectric n. materials particularly valuable in the development of non-volatile memory devices, such as ferroelectric random access memory (FeRAM).Moreover, ferroelectric n. materials have been found to possess piezoelectric properties, meaning they can generate an electric charge in response to applied mechanical stress. This dual functionality enhances their applicability in various fields, including actuators, which convert electrical energy into mechanical motion. For instance, in medical ultrasound devices, ferroelectric n. materials can be used to generate sound waves, enabling non-invasive imaging techniques.The research surrounding ferroelectric n. materials is continually evolving, with scientists exploring new compounds and structures to enhance their performance. Recent studies have focused on organic ferroelectric n. materials, which offer advantages such as flexibility and ease of processing compared to traditional inorganic counterparts. These organic variants hold promise for future applications in flexible electronics and wearable devices.In addition to their technological applications, ferroelectric n. materials also present intriguing challenges for researchers. Understanding the mechanisms behind their polarization switching and the factors that influence their stability is crucial for optimizing their performance in practical applications. Researchers are employing advanced characterization techniques to gain insights into the microscopic behavior of ferroelectric n. materials, paving the way for innovations in material design and engineering.In conclusion, the study of ferroelectric n. materials represents a vibrant and promising area of research within materials science. With their unique properties and wide-ranging applications, ferroelectric n. materials are poised to play a critical role in the development of next-generation electronic devices. As we continue to explore and understand these fascinating materials, we can anticipate exciting advancements that will shape the future of technology. The ongoing research in this field not only enhances our understanding of material properties but also opens up new possibilities for innovation and application in various industries.

近年来，材料科学领域见证了显著的进步，特别是在对各种材料特性的研究方面。其中一个引人注目的特性是铁电性 n.。这个术语指的是一类材料，它们表现出自发的电极化，可以通过施加外部电场来逆转。铁电性 n.材料的意义深远，应用范围从存储设备到传感器和执行器。铁电性 n.材料的独特特性源于它们的晶体结构，这使得电偶极子的排列成为可能。这种排列导致在没有外部电场的情况下仍然存在永久的电极化。当施加外部电场时，极化可以被切换，从而实现信息的存储和操控。这种切换极化的能力使得铁电性 n.材料在开发非易失性存储设备（如铁电随机存取存储器 FeRAM）中尤为宝贵。此外，铁电性 n.材料还发现具有压电特性，这意味着它们可以在施加机械应力时产生电荷。这种双重功能增强了它们在各个领域的适用性，包括将电能转换为机械运动的执行器。例如，在医学超声设备中，铁电性 n.材料可以用于生成声波，从而实现非侵入性的成像技术。围绕铁电性 n.材料的研究不断发展，科学家们正在探索新的化合物和结构，以提高其性能。最近的研究集中在有机铁电性 n.材料上，与传统无机材料相比，这些材料具有灵活性和易于加工的优点。这些有机变体在未来的柔性电子和可穿戴设备中展现了潜力。除了技术应用之外，铁电性 n.材料还给研究人员带来了有趣的挑战。理解其极化切换背后的机制以及影响其稳定性的因素，对于优化实际应用中的性能至关重要。研究人员正在采用先进的表征技术，以深入了解铁电性 n.材料的微观行为，为材料设计和工程的创新铺平道路。总之，铁电性 n.材料的研究代表了材料科学中一个充满活力和前景广阔的研究领域。凭借其独特的特性和广泛的应用，铁电性 n.材料将在下一代电子设备的发展中发挥关键作用。随着我们继续探索和理解这些迷人的材料，我们可以期待塑造未来技术的激动人心的进展。该领域的持续研究不仅增强了我们对材料特性的理解，还为各个行业的创新和应用开辟了新的可能性。