laser fusion

简明释义

激光核聚变

英英释义

例句

1.Scientists at the lab are conducting experiments on laser fusion 激光聚变 to achieve sustainable energy.

实验室的科学家们正在进行关于激光聚变 laser fusion的实验，以实现可持续能源。

2.The recent advancements in laser fusion 激光聚变 technology could revolutionize power generation.

最近在激光聚变 laser fusion技术上的进展可能会彻底改变发电方式。

3.Researchers are exploring the potential of laser fusion 激光聚变 as a clean energy source.

研究人员正在探索激光聚变 laser fusion作为清洁能源的潜力。

4.Many universities are offering courses in laser fusion 激光聚变 as part of their physics programs.

许多大学将激光聚变 laser fusion作为物理学课程的一部分提供。

5.The military is interested in laser fusion 激光聚变 for its potential applications in advanced weaponry.

军方对激光聚变 laser fusion感兴趣，因为它在先进武器中的潜在应用。

作文

In recent years, the field of energy production has witnessed significant advancements, particularly in the area of nuclear fusion. Among the various methods being explored, laser fusion (激光聚变) has emerged as a promising technology that could potentially provide a nearly limitless source of clean energy. This innovative approach utilizes powerful lasers to heat and compress hydrogen isotopes, ultimately leading to a fusion reaction similar to that which powers the sun. The implications of successfully harnessing laser fusion (激光聚变) are profound, as it could revolutionize the way we generate electricity and reduce our reliance on fossil fuels.The principle behind laser fusion (激光聚变) is relatively straightforward. By focusing intense laser beams onto a small pellet of fusion fuel, typically composed of deuterium and tritium, scientists can achieve the extreme temperatures and pressures necessary for fusion to occur. When these conditions are met, the nuclei of the hydrogen isotopes collide and fuse, releasing a tremendous amount of energy in the process. This energy can then be harnessed to produce electricity, much like conventional power plants do with coal or natural gas.One of the most significant advantages of laser fusion (激光聚变) is its potential to produce energy without the harmful byproducts associated with traditional fossil fuel combustion. Unlike coal or oil, which release greenhouse gases that contribute to climate change, the primary byproduct of fusion is helium, an inert gas that poses no environmental threat. Furthermore, the fuel used in laser fusion (激光聚变) is abundant and widely available, as deuterium can be extracted from seawater and tritium can be bred from lithium, making it a sustainable option for energy generation.Despite the promise of laser fusion (激光聚变), there are still significant challenges that researchers must overcome before it can become a viable energy source. One of the main hurdles is achieving the necessary conditions for fusion to occur in a controlled and sustained manner. Current experiments have demonstrated the feasibility of laser fusion (激光聚变), but sustaining the reaction long enough to produce more energy than is consumed remains a critical goal.Another challenge lies in the technological requirements needed to implement laser fusion (激光聚变) on a large scale. The lasers used in these experiments are incredibly sophisticated and require substantial investment in infrastructure and research. Additionally, the safety and regulatory frameworks surrounding nuclear fusion must be developed to ensure that this new technology can be safely integrated into our energy systems.In conclusion, laser fusion (激光聚变) represents a groundbreaking approach to energy production that holds great promise for the future. As we continue to grapple with the effects of climate change and the depletion of fossil fuel resources, investing in research and development of laser fusion (激光聚变) technology may lead us towards a cleaner, more sustainable energy landscape. While challenges remain, the potential benefits of harnessing the power of the stars to meet our energy needs cannot be overstated. It is an exciting time for scientists and engineers working in this field, and the world watches closely as they strive to unlock the secrets of laser fusion (激光聚变).

近年来，能源生产领域见证了重大进展，特别是在核聚变领域。在各种探索的方法中，laser fusion（激光聚变）作为一种有前景的技术逐渐崭露头角，可能提供近乎无限的清洁能源来源。这种创新方法利用强大的激光来加热和压缩氢同位素，最终导致类似于太阳能量产生的聚变反应。成功掌握laser fusion（激光聚变）的意义深远，因为它可能彻底改变我们发电的方式，并减少对化石燃料的依赖。laser fusion（激光聚变）背后的原理相对简单。通过将强烈的激光束聚焦到一个小的聚变燃料颗粒上，该颗粒通常由氘和氚组成，科学家可以达到进行聚变所需的极端温度和压力。当这些条件满足时，氢同位素的核会碰撞并融合，释放出巨大的能量。这种能量随后可以被利用来发电，就像传统发电厂使用煤或天然气一样。laser fusion（激光聚变）最大的一个优势是，它能够在没有传统化石燃料燃烧所产生的有害副产品的情况下产生能量。与释放温室气体、导致气候变化的煤或石油不同，聚变的主要副产品是氦气，这是一种惰性气体，不会对环境造成威胁。此外，用于laser fusion（激光聚变）的燃料丰富且广泛可用，因为氘可以从海水中提取，而氚可以从锂中繁殖，使其成为一种可持续的能源选择。尽管laser fusion（激光聚变）前景广阔，但研究人员仍然面临重大挑战，必须克服这些挑战，才能使其成为可行的能源来源。主要障碍之一是在受控和持续的方式下实现聚变所需的条件。当前的实验已经证明了laser fusion（激光聚变）的可行性，但维持反应足够长的时间以产生比消耗更多的能量仍然是一个关键目标。另一个挑战是实施laser fusion（激光聚变）所需的技术要求。用于这些实验的激光器非常复杂，需要在基础设施和研究方面进行大量投资。此外，围绕核聚变的安全和监管框架必须得到发展，以确保这一新技术能够安全地融入我们的能源系统。总之，laser fusion（激光聚变）代表了一种突破性的能源生产方法，未来前景广阔。当我们继续应对气候变化的影响以及化石燃料资源的枯竭时，投资于laser fusion（激光聚变）技术的研究与开发，可能会引领我们走向更清洁、更可持续的能源格局。尽管挑战依然存在，但利用星星的力量满足我们能源需求的潜在好处不容小觑。对于在这一领域工作的科学家和工程师而言，这是一个令人兴奋的时代，世界也在密切关注他们努力解锁laser fusion（激光聚变）秘密的过程。