electroactive

简明释义

英[ˌɛlɛkˈtrəʊˌæktɪv]美[ˌɛlɛkˈtræktɪv]

电活性

英英释义

单词用法

同义词

反义词

例句

1.The adjustable focusing electrically controllable electroactive lens can adjust the focal length discretely or continuously.

该可调整焦距的、可电学控制的电激活透镜能够不连续地或连续地调整焦距。

2.Pacinian has researched different deformable materials, including one called electroactive polymers.

帕西尼公司对不同的变形材料进行了研究，包括一种叫电活性聚合物的材料。

3.The characterization of the PAP film by infrared spectroscopy suggested that the PAP is a ladder polymer with phenoxazine rings as electroactive sites.

用红外吸收光谱法表征了聚邻氨基酚薄膜，认为该聚合物具有梯形结构，其中吩恶嗪环作为电活性点。

4.There are two main types of electroactive polymer (EAP), which are usually referred to as ionic and dielectric (see diagram).

电活性聚合物(EAP)主要有两种类型，那就是我们通常所说的离子型和电介质型(见下图)。

5.As a new type of electroactive polymer (EAP), dielectric elastomers can work in both actuator and generator modes.

介电弹性体功能材料是具有优异性能的电场活化聚合物，可在驱动和发电两种模式下工作。

6.Higher the temperature, greater the anodic peak current of CV, and PANI film is more electroactive and has a higher electrochemistry ability of repositing energy on corresponding potential.

温度越高，聚苯胺膜的峰值电流越大，电化学活性越强，聚苯胺在对应电位时的电化学储能能力越强。

7.These are embedded in a spongy "electroactive" polymer.

这些元素深埋在一种海绵“导电”聚合物中。

8.The researchers developed a new type of polymer that is electroactive 电活性的, allowing it to change shape when an electric current is applied.

研究人员开发了一种新型聚合物，它是电活性的，可以在施加电流时改变形状。

9.In the field of robotics, electroactive 电活性的 materials are used to create soft actuators that mimic muscle movement.

在机器人领域，电活性的材料被用来制造模拟肌肉运动的软驱动器。

10.The invention of electroactive 电活性的 ceramics has revolutionized the way sensors are designed.

电活性陶瓷的发明彻底改变了传感器的设计方式。

11.Scientists are exploring electroactive 电活性的 hydrogels for applications in biomedical devices.

科学家们正在探索电活性水凝胶在生物医学设备中的应用。

12.The use of electroactive 电活性的 polymers in smart textiles can lead to clothing that responds to environmental changes.

在智能纺织品中使用电活性聚合物可以使衣物对环境变化做出反应。

作文

Electroactive materials have garnered significant attention in the fields of science and engineering due to their unique properties and wide range of applications. These materials can change their shape, size, or other physical properties in response to an electric field. This fascinating characteristic makes them ideal for various uses, including sensors, actuators, and even in energy harvesting technologies. Understanding the concept of electroactive (电活性的) materials is crucial for advancing modern technology and improving our daily lives. One of the most common examples of electroactive (电活性的) materials is piezoelectric substances. These materials generate an electric charge when mechanically stressed, which allows them to convert mechanical energy into electrical energy. This property is widely utilized in various applications such as microphones, speakers, and pressure sensors. For instance, in smartphones, piezoelectric materials are used in touch screens to detect user input with precision. Another important category of electroactive (电活性的) materials is conducting polymers. These synthetic materials exhibit both electrical conductivity and flexibility, making them suitable for use in flexible electronics. Conducting polymers can be used in organic light-emitting diodes (OLEDs), solar cells, and even in smart textiles that can monitor health metrics. The ability of these materials to conduct electricity while remaining lightweight and pliable opens up new possibilities for wearable technology and portable devices. Moreover, electroactive (电活性的) materials play a crucial role in the development of artificial muscles. Researchers are exploring the use of these materials to create soft robots that can mimic the movements of living organisms. By applying an electric field, these materials can contract or expand, allowing for fluid motion and adaptability. This innovation could revolutionize robotics, leading to more efficient and versatile machines that can operate in complex environments. The integration of electroactive (电活性的) materials into renewable energy systems is another promising area of research. For example, scientists are investigating their use in energy harvesting devices that convert ambient mechanical energy, such as vibrations or wind, into electrical energy. This technology has the potential to power small electronic devices without the need for batteries, contributing to sustainability and reducing electronic waste. Despite the numerous advantages of electroactive (电活性的) materials, challenges remain in their widespread adoption. Issues such as durability, scalability, and cost-effectiveness need to be addressed before these materials can be fully integrated into commercial products. Ongoing research aims to overcome these hurdles by developing new formulations and processing techniques that enhance the performance and longevity of electroactive (电活性的) materials. In conclusion, the study of electroactive (电活性的) materials is a rapidly evolving field with immense potential. As we continue to explore their unique properties and applications, we can expect to see significant advancements in technology that will improve our quality of life. From flexible electronics to renewable energy solutions, the impact of electroactive (电活性的) materials on our future is undoubtedly profound. Embracing this knowledge will not only help us innovate but also inspire the next generation of scientists and engineers to push the boundaries of what is possible.