ambipolar
发音:英 [,?mb?'p??l?] 美 [,?mb?'p??l?]
释义:两性的;两极化的;两极性的
英语范文:I think ambipolar is a good characteristic for a leader. It means that they can see both sides of an issue and make a decision based on that.
翻译:我认为两极性是一个好的领导特质。这意味着他们能看到问题的两个方面,并基于这些做出决定。
以上内容仅供参考,建议使用英语与他人进行交流和沟通。
Ambipolar
Ambipolar is a term used in chemistry to describe a property where a substance has both polar and non-polar properties. This term is particularly important in the field of organic chemistry, where molecules can have both positive and negative charges, leading to a balance between the two.
In organic solar cells, ambipolar behavior plays a crucial role. The charge carriers in these cells can move freely in both directions, allowing for efficient collection of solar energy. This allows for a higher efficiency in converting sunlight into electricity, making ambipolar behavior a key factor in the development of sustainable energy sources.
In addition to its use in solar cells, ambipolar behavior is also important in other areas such as electronics, sensors, and biotechnology. Understanding the behavior of ambipolar materials and their interactions with other substances is essential for the development of new technologies that are more efficient and sustainable.
Overall, ambipolar behavior is a fundamental property that plays a crucial role in many areas of science and technology. Understanding this behavior and harnessing it for sustainable development will be essential for the future of our planet.
"ambipolar"是一个英语单词,意思是"双极性的"。在物理学中,双极性指的是物质或现象中同时存在正负电荷的性质。
发音:/?m?b?p??l?/
以下是一篇关于"ambipolar"的英语作文,供您参考:
In physics, the concept of ambipolar refers to a phenomenon where a substance or process exhibits both positive and negative charges simultaneously. This phenomenon is crucial in many areas of research, including electronics, chemistry, and materials science.
For instance, in the field of electronics, ambipolar technology is used to create transistors and other components that can operate at high frequencies and low power consumption. By incorporating ambipolar principles, designers can create devices that are more efficient and reliable than traditional silicon-based technologies.
Moreover, in the field of materials science, ambipolar materials are used in solar cells and other energy conversion systems. These materials can absorb light of various wavelengths and convert them into electricity with high efficiency. This allows for the development of more sustainable and efficient energy systems that are less reliant on traditional fossil fuels.
Overall, the concept of ambipolar is essential in many fields of research and has the potential to revolutionize the way we approach various scientific challenges. Understanding and harnessing the power of ambipolar principles can lead to breakthroughs in areas such as energy conversion, electronics, and more.
