hydrogen carrier

简明释义

氢载体

英英释义

例句

1.Liquid organic hydrogen carriers (LOHC) serve as efficient hydrogen carriers (氢载体) for transport and storage.

液态有机氢载体（LOHC）作为高效的氢载体（氢载体）用于运输和存储。

2.Researchers are exploring various materials as potential hydrogen carriers (氢载体) for fuel cell applications.

研究人员正在探索各种材料作为燃料电池应用的潜在氢载体（氢载体）。

3.In recent studies, metal hydrides have been identified as promising hydrogen carriers (氢载体).

最近的研究表明，金属氢化物被认为是有前景的氢载体（氢载体）。

4.The use of ammonia as a hydrogen carrier (氢载体) is gaining popularity in the renewable energy sector.

氨作为氢载体（氢载体）在可再生能源领域越来越受欢迎。

5.The development of a new hydrogen carrier (氢载体) can significantly enhance energy storage capabilities.

新型氢载体（氢载体）的开发可以显著增强能源存储能力。

作文

As the world moves towards a more sustainable future, the importance of alternative energy sources has become increasingly evident. One such promising avenue is the use of hydrogen as a clean energy carrier. A hydrogen carrier refers to a substance that can store and transport hydrogen in a safe and efficient manner. This concept is crucial because while hydrogen itself is a clean fuel, its storage and transportation pose significant challenges due to its low density and high flammability. There are various types of hydrogen carriers, including liquid organic hydrogen carriers (LOHCs), metal hydrides, and ammonia. Each of these carriers has unique properties that make them suitable for different applications. For instance, LOHCs can absorb and release hydrogen through chemical reactions, allowing for easier handling at ambient temperatures and pressures. On the other hand, metal hydrides can store hydrogen in a solid form, which can be advantageous for certain industrial applications.The use of hydrogen carriers offers several benefits. First, they can significantly reduce the volume required for hydrogen storage, making it more feasible to transport over long distances. This is particularly important for regions that produce hydrogen but lack the infrastructure to utilize it locally. By utilizing hydrogen carriers, we can create a more integrated energy market where hydrogen can be transported from production sites to consumption areas efficiently.Moreover, hydrogen carriers can also facilitate the transition to renewable energy sources. For example, excess energy generated from solar or wind power can be used to produce hydrogen through electrolysis. This hydrogen can then be converted into a hydrogen carrier for storage and later use when energy demand peaks or when renewable sources are not producing enough energy. This process not only helps in balancing supply and demand but also contributes to reducing greenhouse gas emissions.Despite the advantages, there are still challenges to overcome in the widespread adoption of hydrogen carriers. The efficiency of the conversion processes, the cost of production, and the need for advanced infrastructure are all critical factors that need attention. Research and development are ongoing to improve the technologies involved and to make hydrogen carriers a more viable option for energy storage and transportation.In conclusion, the role of hydrogen carriers in the future energy landscape cannot be underestimated. They represent a crucial step towards achieving a hydrogen economy, where hydrogen can be stored, transported, and utilized effectively. As we continue to innovate and invest in this area, hydrogen carriers could play a pivotal role in our quest for sustainable energy solutions, enabling us to harness the full potential of hydrogen as a clean and versatile energy source.

随着世界朝着更可持续的未来发展，替代能源的重要性变得越来越明显。其中一种有前景的途径是将氢气作为清洁能源载体。氢载体指的是能够以安全和高效的方式存储和运输氢气的物质。这个概念至关重要，因为虽然氢气本身是一种清洁燃料，但由于其低密度和高易燃性，其存储和运输面临重大挑战。有多种类型的氢载体，包括液体有机氢载体（LOHC）、金属氢化物和氨。每种载体都有独特的特性，使其适合不同的应用。例如，LOHC可以通过化学反应吸收和释放氢气，从而允许在常温常压下更容易处理。另一方面，金属氢化物可以以固体形式存储氢气，这对于某些工业应用可能是有利的。使用氢载体提供了几种好处。首先，它们可以显著减少氢气存储所需的体积，使其更易于长距离运输。这对于那些生产氢气但缺乏利用基础设施的地区尤为重要。通过利用氢载体，我们可以创建一个更为综合的能源市场，使氢气能够高效地从生产地点运输到消费区域。此外，氢载体还可以促进向可再生能源的过渡。例如，来自太阳能或风能的多余能源可以用于通过电解水生产氢气。这种氢气随后可以转化为氢载体进行存储，并在能源需求高峰时或可再生能源未能产生足够能源时使用。这个过程不仅有助于平衡供需，还能减少温室气体排放。尽管有这些优势，广泛采用氢载体仍然面临挑战。转换过程的效率、生产成本以及对先进基础设施的需求都是需要关注的关键因素。研究和开发正在进行中，以改善相关技术，使氢载体成为能源存储和运输的更可行选择。总之，氢载体在未来能源格局中的角色不可低估。它们代表着实现氢经济的关键一步，在这种经济中，氢气可以有效地存储、运输和利用。随着我们继续在这一领域进行创新和投资，氢载体可能在我们追求可持续能源解决方案的过程中发挥关键作用，使我们能够充分利用氢气作为清洁和多功能的能源来源。