fixed crystal

简明释义

固定晶伐;

英英释义

例句

1.The fixed crystal in this device enhances its durability and performance.

该设备中的固定水晶增强了其耐用性和性能。

2.The fixed crystal allows for a clear view of the dial without distortion.

该固定水晶允许清晰地查看表盘而没有失真。

3.When replacing the fixed crystal, make sure to choose the correct size.

更换固定水晶时，请确保选择正确的尺寸。

4.In our laboratory, we often analyze samples with a fixed crystal setup for better precision.

在我们的实验室中，我们经常使用固定水晶装置来分析样品，以获得更好的精度。

5.The watch uses a fixed crystal to ensure accurate timekeeping.

这款手表使用了固定水晶以确保准确的计时。

作文

In the realm of science and technology, the term fixed crystal refers to a type of crystalline structure that remains stable and unchanged under specific conditions. This stability is crucial in various applications, especially in electronics and telecommunications. The properties of fixed crystals allow them to maintain their integrity over time, making them ideal for use in devices such as oscillators, filters, and resonators. Understanding the significance of fixed crystals can provide insights into their role in modern technology.One of the primary characteristics of a fixed crystal is its ability to vibrate at a consistent frequency. This feature is essential for the functioning of quartz watches, where the fixed crystal regulates timekeeping with remarkable accuracy. The quartz crystal oscillates when an electric current is applied, generating a precise frequency that keeps the watch running smoothly. Without the fixed crystal, the accuracy of timekeeping would be severely compromised.Moreover, fixed crystals are also widely used in communication devices. For instance, radio transmitters and receivers rely on these crystals to filter signals and maintain clear communication channels. The stability of the fixed crystal ensures that the signals transmitted and received are consistent, reducing interference and improving overall performance. This reliability is why fixed crystals are often preferred in high-frequency applications, where precision is paramount.In addition to their application in electronics, fixed crystals have significant implications in the field of materials science. Researchers are continuously exploring new ways to manipulate the properties of these crystals to enhance their performance. For example, by doping a fixed crystal with certain impurities, scientists can alter its electrical conductivity or optical properties. This research not only broadens our understanding of material behavior but also paves the way for the development of advanced technologies, such as photonic devices and sensors.Furthermore, the study of fixed crystals extends beyond practical applications; it also delves into the fundamental principles of crystallography. Crystallographers investigate the arrangement of atoms within a fixed crystal, seeking to understand how this arrangement influences the material's properties. Through techniques such as X-ray diffraction, researchers can visualize the internal structure of fixed crystals, providing valuable data that informs both theoretical and practical advancements in science.As we look to the future, the importance of fixed crystals is only expected to grow. With the rapid advancement of technology, the demand for reliable and efficient materials will increase. Innovations in fields like quantum computing, where fixed crystals may play a crucial role in qubit stability, highlight the ongoing relevance of these structures. The exploration of fixed crystals offers a glimpse into the potential of materials science to revolutionize our world, making it an exciting area of study.In conclusion, the concept of fixed crystal encompasses a wide range of applications and implications in both technology and science. Their stability, reliability, and unique properties make them indispensable in various industries. As research continues to evolve, the understanding and utilization of fixed crystals will undoubtedly lead to new innovations and advancements that shape our future.

在科学和技术领域，术语固定晶体指的是在特定条件下保持稳定和不变的一种晶体结构。这种稳定性在各种应用中至关重要，特别是在电子和电信领域。固定晶体的特性使其能够随着时间的推移保持完整性，使其成为振荡器、滤波器和谐振器等设备的理想选择。理解固定晶体的重要性可以提供对其在现代技术中角色的深入见解。固定晶体的主要特征之一是其在一致频率下振动的能力。这一特性对于石英手表的运作至关重要，其中固定晶体以极高的精确度调节计时。施加电流时，石英晶体会振荡，产生一个精确的频率，使手表顺利运行。如果没有固定晶体，计时的准确性将受到严重影响。此外，固定晶体也广泛应用于通信设备。例如，无线电发射器和接收器依赖这些晶体来过滤信号并保持清晰的通信通道。固定晶体的稳定性确保了传输和接收的信号一致，减少了干扰，提高了整体性能。这种可靠性是固定晶体在高频应用中常被优先选择的原因，因为在这些应用中，精确性至关重要。除了在电子学中的应用外，固定晶体在材料科学领域也具有重要意义。研究人员不断探索操纵这些晶体性质的新方法，以增强其性能。例如，通过掺杂某些杂质，科学家可以改变固定晶体的电导率或光学特性。这项研究不仅拓宽了我们对材料行为的理解，还为开发先进技术（如光子设备和传感器）铺平了道路。此外，固定晶体的研究不仅限于实际应用；它还深入探讨了晶体学的基本原理。晶体学家研究固定晶体中原子的排列，试图理解这种排列如何影响材料的性质。通过X射线衍射等技术，研究人员可以可视化固定晶体的内部结构，提供有价值的数据，推动理论和实践的进步。展望未来，固定晶体的重要性只会增加。随着技术的快速发展，对可靠和高效材料的需求将不断上升。在量子计算等领域的创新中，固定晶体可能在量子位稳定性方面发挥关键作用，突显了这些结构的持续相关性。对固定晶体的探索提供了材料科学潜力的一个视角，可能会改变我们的世界，使其成为一个令人兴奋的研究领域。总之，固定晶体的概念涵盖了技术和科学中广泛的应用和意义。它们的稳定性、可靠性和独特特性使其在各个行业中不可或缺。随着研究的不断发展，对固定晶体的理解和利用无疑会导致塑造我们未来的新创新和进步。