low temperature passivation

简明释义

低温钝化

英英释义

例句

1.We applied low temperature passivation to ensure better performance of our solar cells.

我们应用了低温钝化以确保太阳能电池的更好性能。

2.The research focused on the effects of low temperature passivation on metal oxide semiconductors.

研究集中在低温钝化对金属氧化物半导体的影响上。

3.The process of low temperature passivation is essential for enhancing the durability of electronic components.

进行低温钝化的过程对于提高电子元件的耐用性至关重要。

4.In semiconductor manufacturing, low temperature passivation helps in reducing defects on the surface.

在半导体制造中，低温钝化有助于减少表面缺陷。

5.Using low temperature passivation, we can improve the reliability of our devices under harsh conditions.

通过使用低温钝化，我们可以提高设备在恶劣条件下的可靠性。

作文

In the field of materials science and semiconductor fabrication, the term low temperature passivation refers to a process that enhances the stability and performance of electronic devices at lower temperatures. This technique is particularly crucial in applications where heat-sensitive materials are involved. The primary goal of low temperature passivation is to create a protective layer that prevents unwanted chemical reactions and physical degradation of the underlying material. The significance of low temperature passivation can be observed in various industries, including electronics, optics, and even renewable energy sectors. For instance, in semiconductor manufacturing, devices like transistors and diodes often require passivation to improve their reliability and efficiency. Traditional passivation methods typically involve high-temperature treatments, which can damage sensitive components or alter their properties. Therefore, developing a low temperature passivation method allows manufacturers to protect these components without compromising their integrity.Moreover, low temperature passivation can enhance the performance of solar cells. In photovoltaic technology, the efficiency of solar cells is significantly affected by surface defects and contamination. By applying a low temperature passivation technique, manufacturers can reduce recombination losses and improve the overall efficiency of solar panels. This not only leads to better energy conversion rates but also extends the lifespan of the solar cells, making them more cost-effective over time.Furthermore, the environmental impact of low temperature passivation processes is worth mentioning. As the world moves towards more sustainable manufacturing practices, reducing the energy consumption associated with high-temperature processes becomes increasingly important. By utilizing low temperature passivation, companies can minimize their carbon footprint and adhere to stricter environmental regulations. This shift not only benefits the planet but also aligns with the growing consumer demand for eco-friendly products.In conclusion, low temperature passivation is an essential advancement in the field of material science and semiconductor technology. It offers numerous benefits, including improved device performance, enhanced durability, and reduced environmental impact. As research continues to evolve, we can expect further innovations in low temperature passivation techniques, paving the way for more efficient and sustainable electronic devices in the future. The ongoing exploration of this method highlights its importance in modern technology and its potential to transform various industries, ensuring that we can meet the demands of a rapidly changing world while preserving the integrity of our materials.

在材料科学和半导体制造领域，短语低温钝化指的是一种在较低温度下增强电子设备稳定性和性能的工艺。这种技术在涉及热敏感材料的应用中尤为重要。低温钝化的主要目标是创建一层保护膜，以防止底层材料发生不必要的化学反应和物理降解。低温钝化的重要性可以在多个行业中观察到，包括电子、光学甚至可再生能源领域。例如，在半导体制造中，像晶体管和二极管这样的设备通常需要钝化以提高其可靠性和效率。传统的钝化方法通常涉及高温处理，这可能会损坏敏感组件或改变其属性。因此，开发一种低温钝化方法使制造商能够在不妥协组件完整性的情况下保护这些组件。此外，低温钝化可以提高太阳能电池的性能。在光伏技术中，太阳能电池的效率受到表面缺陷和污染的显著影响。通过应用低温钝化技术，制造商可以减少复合损失，提高太阳能电池的整体效率。这不仅导致更好的能量转换率，还延长了太阳能电池的使用寿命，使其在长期内更具成本效益。此外，值得一提的是低温钝化过程对环境的影响。随着世界向更可持续的制造实践迈进，减少与高温工艺相关的能源消耗变得越来越重要。通过利用低温钝化，公司可以最小化其碳足迹，并遵守更严格的环境法规。这种转变不仅有利于地球，也符合日益增长的消费者对环保产品的需求。总之，低温钝化是材料科学和半导体技术领域的一项重要进展。它提供了许多好处，包括改善设备性能、增强耐用性和减少环境影响。随着研究的不断发展，我们可以期待在低温钝化技术方面进一步创新，为未来更高效和可持续的电子设备铺平道路。对这一方法的持续探索突显了其在现代技术中的重要性及其转变各个行业的潜力，确保我们能够满足快速变化的世界的需求，同时保护材料的完整性。