lateral photovoltaic effect

简明释义

横向光生伏打效应

英英释义

例句

1.Understanding the lateral photovoltaic effect 侧向光伏效应 is crucial for developing advanced photovoltaic materials.

理解侧向光伏效应 lateral photovoltaic effect 对于开发先进的光伏材料至关重要。

2.Researchers are exploring how the lateral photovoltaic effect 侧向光伏效应 can be utilized in flexible solar panels.

研究人员正在探索如何在柔性太阳能电池板中利用侧向光伏效应 lateral photovoltaic effect。

3.The research team discovered that the lateral photovoltaic effect 侧向光伏效应 could significantly enhance the efficiency of solar cells.

研究团队发现，侧向光伏效应 lateral photovoltaic effect 可以显著提高太阳能电池的效率。

4.The lateral photovoltaic effect 侧向光伏效应 can lead to new designs in solar energy harvesting technologies.

侧向光伏效应 lateral photovoltaic effect 可以引领太阳能收集技术的新设计。

5.In their experiments, they measured the lateral photovoltaic effect 侧向光伏效应 under various light intensities.

在他们的实验中，他们测量了不同光强下的侧向光伏效应 lateral photovoltaic effect。

作文

The world is continuously evolving towards renewable energy sources, and one of the most fascinating phenomena in this field is the Lateral Photovoltaic Effect. This effect refers to the generation of electrical current in a material when it is illuminated from the side, rather than directly from above. Traditional photovoltaic cells capture sunlight primarily from the top surface, but the Lateral Photovoltaic Effect opens up new avenues for solar energy harnessing. Understanding this effect can lead to innovative designs for solar panels that are more efficient and versatile.The Lateral Photovoltaic Effect occurs due to the unique properties of certain materials, particularly semiconductors. When light hits these materials, it creates electron-hole pairs. In a typical solar cell, these charge carriers would move towards the electrodes, generating electricity. However, in the case of the Lateral Photovoltaic Effect, the illumination from the side allows for a different movement of these charge carriers, which can enhance the efficiency of energy conversion.This phenomenon has significant implications for the design of solar panels. For instance, using materials that exhibit the Lateral Photovoltaic Effect could lead to thinner and lighter solar panels, which can be integrated into various surfaces, such as windows or building facades. This would not only save space but also allow for the aesthetic incorporation of solar technology into urban environments. Imagine a skyscraper where the glass panels not only provide a view but also generate power through the Lateral Photovoltaic Effect.Moreover, the Lateral Photovoltaic Effect can potentially improve the performance of solar panels in low-light conditions. As urban areas often experience shading from buildings or trees, having a technology that can capture lateral light can significantly boost energy production. This adaptability makes it an attractive option for future solar technologies.Research into the Lateral Photovoltaic Effect is still ongoing, and scientists are exploring various materials and configurations to optimize its performance. The development of nanostructured materials could enhance this effect, leading to even greater efficiencies. As we face the challenges of climate change and the need for sustainable energy solutions, understanding and harnessing the Lateral Photovoltaic Effect could play a crucial role in our transition to a greener future.In conclusion, the Lateral Photovoltaic Effect represents an exciting frontier in solar energy research. Its potential to revolutionize the way we capture and use solar energy cannot be overstated. By integrating this phenomenon into modern technology, we can pave the way for more efficient, versatile, and aesthetically pleasing solar energy solutions. As we continue to innovate in this field, the possibilities seem endless, and the Lateral Photovoltaic Effect may very well be a key player in the energy landscape of tomorrow.

世界正在不断向可再生能源转型，而在这一领域中，最令人着迷的现象之一就是横向光伏效应。该效应指的是当材料从侧面照射时产生电流，而不是直接从上方照射。传统的光伏电池主要从顶部捕获阳光，但横向光伏效应为太阳能利用开辟了新的途径。理解这一效应可以导致太阳能电池板的创新设计，使其更加高效和多功能。横向光伏效应发生在某些材料，特别是半导体的独特性质下。当光照射到这些材料上时，会产生电子-空穴对。在典型的太阳能电池中，这些电荷载流子会向电极移动，从而产生电力。然而，在横向光伏效应的情况下，侧面的照明允许这些电荷载流子以不同的方式移动，从而可以提高能量转换的效率。这一现象对太阳能电池板的设计具有重要意义。例如，使用表现出横向光伏效应的材料可能导致更薄、更轻的太阳能电池板，这些电池板可以集成到各种表面上，如窗户或建筑外立面。这不仅节省了空间，还允许将太阳能技术美观地融入城市环境中。想象一下，一座摩天大楼的玻璃面板不仅提供了视野，还通过横向光伏效应产生电力。此外，横向光伏效应可能改善太阳能电池板在低光条件下的性能。由于城市地区常常受到建筑物或树木的遮荫，拥有能够捕捉侧面光线的技术可以显著提高能量生产。这种适应性使其成为未来太阳能技术的一个有吸引力的选择。对横向光伏效应的研究仍在进行中，科学家们正在探索各种材料和配置以优化其性能。纳米结构材料的发展可能增强这一效应，从而导致更高的效率。面对气候变化的挑战以及对可持续能源解决方案的需求，理解和利用横向光伏效应可能在我们向绿色未来的过渡中发挥关键作用。总之，横向光伏效应代表了太阳能研究中的一个令人兴奋的前沿。它对革命性改变我们捕获和利用太阳能的方式的潜力不容小觑。通过将这一现象整合到现代技术中，我们可以为更高效、多功能和美观的太阳能解决方案铺平道路。随着我们在这一领域的不断创新，可能性似乎是无穷无尽的，而横向光伏效应很可能成为未来能源格局的关键参与者。