synthetic piezoelectric crystal

简明释义

人造压电晶体

英英释义

例句

1.Engineers are developing new types of synthetic piezoelectric crystals for more efficient actuators.

工程师们正在开发新型的合成压电晶体以实现更高效的执行器。

2.The new smartphone features a built-in sensor made from a synthetic piezoelectric crystal, which enhances its touch responsiveness.

这款新智能手机配备了一种由合成压电晶体制成的内置传感器，增强了其触摸响应能力。

3.The durability of synthetic piezoelectric crystals makes them ideal for harsh environmental conditions.

由于耐用性，合成压电晶体非常适合恶劣的环境条件。

4.Researchers are exploring the use of synthetic piezoelectric crystals in energy harvesting applications.

研究人员正在探索在能量收集应用中使用合成压电晶体。

5.The synthetic piezoelectric crystal used in medical ultrasound devices improves image quality significantly.

医疗超声设备中使用的合成压电晶体显著提高了图像质量。

作文

The world of materials science is constantly evolving, with new discoveries and innovations paving the way for advanced applications in various fields. One such innovation is the development of synthetic piezoelectric crystals, which have garnered significant attention due to their unique properties and wide-ranging uses. These crystals are engineered to exhibit piezoelectricity, a phenomenon where mechanical stress is converted into electrical energy and vice versa. This property makes them invaluable in numerous technologies, including sensors, actuators, and energy harvesting devices.Synthetic piezoelectric crystals are created through controlled processes that allow scientists to manipulate their structure at the molecular level. Unlike natural piezoelectric materials, which can be limited in availability and performance, synthetic piezoelectric crystals can be tailored to meet specific requirements. This customization is crucial for applications that demand high precision and efficiency.One of the most notable advantages of synthetic piezoelectric crystals is their ability to generate electricity from mechanical vibrations. For example, when these crystals are placed in environments with constant movement, such as in machinery or even in wearable technology, they can convert that kinetic energy into electrical energy. This capability opens up new possibilities for self-powered devices, reducing reliance on traditional power sources and contributing to sustainability efforts.In addition to energy generation, synthetic piezoelectric crystals play a vital role in sensor technology. They are used in various applications, from medical imaging equipment to industrial monitoring systems. When pressure is applied to these crystals, they produce an electrical signal that can be measured and analyzed. This property allows for precise detection of changes in pressure, force, or even sound waves, making them essential components in many modern devices.Moreover, the versatility of synthetic piezoelectric crystals extends to their use in actuators, which are devices that convert electrical energy into mechanical motion. In robotics and automation, these crystals can enable precise movements and control, enhancing the functionality of machines. As industries continue to embrace automation, the demand for efficient actuators powered by synthetic piezoelectric crystals is expected to rise.The research and development of synthetic piezoelectric crystals are ongoing, with scientists exploring new materials and fabrication techniques to enhance their performance. Recent advancements have led to the creation of composites that combine piezoelectric crystals with other materials, resulting in improved durability and functionality. These innovations hold the potential to revolutionize various sectors, including healthcare, automotive, and renewable energy.In conclusion, synthetic piezoelectric crystals represent a significant advancement in materials science, offering unique properties that are applicable across a wide range of technologies. Their ability to convert mechanical energy into electrical energy, coupled with their versatility in sensors and actuators, makes them a key player in the development of innovative solutions for modern challenges. As research continues to uncover new possibilities, the impact of synthetic piezoelectric crystals on our daily lives is likely to grow, paving the way for a more sustainable and technologically advanced future.

材料科学的世界不断发展，新发现和创新为各个领域的先进应用铺平了道路。其中一个这样的创新是合成压电晶体的开发，由于其独特的特性和广泛的用途，受到了显著关注。这些晶体经过工程设计，以表现出压电效应，这是一种机械应力转化为电能的现象，反之亦然。这一特性使它们在传感器、执行器和能量收集设备等众多技术中变得无价。合成压电晶体通过控制过程制造，使科学家能够在分子层面上操控其结构。与天然压电材料相比，后者在可用性和性能上可能受到限制，合成压电晶体可以定制以满足特定需求。这种定制对要求高精度和高效率的应用至关重要。合成压电晶体最显著的优势之一是它们能够从机械振动中产生电力。例如，当这些晶体放置在持续运动的环境中，如机器或甚至可穿戴技术中时，它们可以将动能转化为电能。这种能力为自供电设备开辟了新的可能性，减少了对传统电源的依赖，并有助于可持续发展。除了能量生成，合成压电晶体在传感器技术中也发挥着重要作用。它们用于各种应用，从医学成像设备到工业监测系统。当施加压力时，这些晶体会产生可以测量和分析的电信号。这一特性允许精确检测压力、力甚至声波的变化，使它们成为许多现代设备中的基本组成部分。此外，合成压电晶体的多功能性还扩展到它们在执行器中的应用，执行器是将电能转化为机械运动的设备。在机器人和自动化中，这些晶体可以实现精确的运动和控制，提高机器的功能性。随着各行业继续拥抱自动化，基于合成压电晶体的高效执行器的需求预计将会增加。合成压电晶体的研究与开发正在进行中，科学家们正在探索新材料和制造技术，以增强其性能。最近的进展导致了复合材料的创建，将压电晶体与其他材料结合， resulting in improved durability and functionality。这些创新有潜力彻底改变包括医疗保健、汽车和可再生能源在内的各个行业。总之，合成压电晶体代表了材料科学的重要进展，提供了适用于广泛技术的独特特性。它们将机械能转化为电能的能力，加上它们在传感器和执行器中的多功能性，使它们成为开发创新解决方案以应对现代挑战的关键因素。随着研究继续揭示新的可能性，合成压电晶体对我们日常生活的影响可能会不断增长，为一个更可持续和技术先进的未来铺平道路。