carbide fuelled breeder

简明释义

碳化物燃料增殖反应堆

英英释义

例句

1.The conference featured a presentation on the advancements in carbide fuelled breeders and their potential impact on energy policy.

会议上展示了关于碳化物燃料繁殖反应堆进展的演讲及其对能源政策的潜在影响。

2.The design of a carbide fuelled breeder requires careful consideration of material properties and reactor dynamics.

设计碳化物燃料繁殖反应堆时需要仔细考虑材料特性和反应堆动力学。

3.Engineers are exploring the benefits of using a carbide fuelled breeder in next-generation reactors.

工程师们正在探索在下一代反应堆中使用碳化物燃料繁殖反应堆的好处。

4.In nuclear engineering, a carbide fuelled breeder can significantly enhance the sustainability of fuel resources.

在核工程中，碳化物燃料繁殖反应堆可以显著增强燃料资源的可持续性。

5.The research team developed a new model of a carbide fuelled breeder that promises higher efficiency in energy production.

研究小组开发了一种新的碳化物燃料繁殖反应堆模型，承诺在能源生产中实现更高的效率。

作文

The world is constantly evolving, and with it, the quest for sustainable energy sources has become more critical than ever. One of the innovative concepts that have emerged in the field of nuclear energy is the carbide fuelled breeder. This technology promises to enhance the efficiency of nuclear reactors while minimizing waste and maximizing energy output. In this essay, I will explore what a carbide fuelled breeder is, how it works, and its potential benefits for our future energy needs.A carbide fuelled breeder is a type of nuclear reactor that uses carbide compounds as fuel. Carbides are chemical compounds that consist of carbon and a less electronegative element. In the context of nuclear energy, these compounds can be used to create a highly efficient fuel cycle. The primary advantage of using carbide as a fuel source is its ability to withstand high temperatures and its excellent thermal conductivity. This means that a carbide fuelled breeder can operate at higher temperatures than traditional reactors, leading to improved thermal efficiency.The operation of a carbide fuelled breeder involves the breeding of fissile material. In simple terms, breeding refers to the process of converting non-fissile materials into fissile ones, which can sustain a nuclear chain reaction. This is achieved by utilizing fast neutrons produced during the fission process. The design of the carbide fuelled breeder allows it to capture these fast neutrons effectively, promoting the conversion of fertile materials, such as uranium-238, into plutonium-239, which is fissile.One of the significant benefits of a carbide fuelled breeder is its potential to close the nuclear fuel cycle. Traditional nuclear reactors often produce a large amount of nuclear waste, which poses a significant environmental challenge. However, the breeding process in a carbide fuelled breeder can significantly reduce the amount of waste generated. By converting fertile materials into usable fuel, these reactors can create more energy than they consume, thus contributing to a more sustainable energy future.Moreover, the use of carbide as a fuel source can also enhance safety. The high thermal conductivity of carbide materials means that they can dissipate heat more effectively, reducing the risk of overheating and potential meltdowns. This feature is particularly important in the wake of past nuclear disasters, where safety concerns have led to increased scrutiny of nuclear energy technologies. A carbide fuelled breeder could offer a safer alternative while still providing the necessary energy output to meet global demands.In conclusion, the carbide fuelled breeder represents a promising advancement in nuclear technology. By utilizing carbide compounds as fuel, these reactors can improve efficiency, reduce waste, and enhance safety. As the world continues to search for sustainable energy solutions, the development and implementation of carbide fuelled breeders could play a crucial role in meeting our future energy needs while addressing environmental concerns. Embracing such innovative technologies will be vital for ensuring a cleaner, safer, and more sustainable energy landscape for generations to come.

世界在不断发展，与此同时，寻找可持续能源的需求变得比以往任何时候都更加迫切。在核能领域，出现了一种创新概念——碳化物燃料增殖反应堆。这一技术有望提高核反应堆的效率，同时最小化废物并最大化能量输出。在这篇文章中，我将探讨什么是碳化物燃料增殖反应堆，它是如何工作的，以及它对我们未来能源需求的潜在好处。碳化物燃料增殖反应堆是一种使用碳化物化合物作为燃料的核反应堆。碳化物是由碳和一种电负性较低的元素组成的化学化合物。在核能的背景下，这些化合物可以用来创建一个高效的燃料循环。使用碳化物作为燃料来源的主要优点是其能够承受高温以及出色的热导率。这意味着碳化物燃料增殖反应堆可以在比传统反应堆更高的温度下运行，从而提高热效率。碳化物燃料增殖反应堆的操作涉及到裂变材料的增殖。简单来说，增殖是指将非裂变材料转化为裂变材料的过程，这些材料可以维持核链反应。这是通过利用在裂变过程中产生的快速中子来实现的。碳化物燃料增殖反应堆的设计使其能够有效捕捉这些快速中子，促进肥料材料（如铀-238）转化为裂变材料铀-239。碳化物燃料增殖反应堆的一个重要好处是其潜力可以关闭核燃料循环。传统核反应堆通常会产生大量核废物，这对环境构成了重大挑战。然而，碳化物燃料增殖反应堆中的增殖过程可以显著减少产生的废物数量。通过将肥料材料转化为可用燃料，这些反应堆可以产生超过其消耗的能量，从而为更可持续的能源未来做出贡献。此外，使用碳化物作为燃料来源也可以增强安全性。碳化物材料的高热导率意味着它们可以更有效地散热，从而降低过热和潜在熔毁的风险。考虑到过去核灾难后的情况，这一特性尤为重要，因为安全问题导致核能技术受到越来越多的审查。碳化物燃料增殖反应堆可以提供一种更安全的替代方案，同时仍然提供满足全球需求的必要能量输出。总之，碳化物燃料增殖反应堆代表了核技术的一项有希望的进步。通过利用碳化物化合物作为燃料，这些反应堆可以提高效率、减少废物并增强安全性。随着世界继续寻找可持续的能源解决方案，碳化物燃料增殖反应堆的发展和实施可能在满足我们未来能源需求的同时，解决环境问题方面发挥关键作用。拥抱这样的创新技术对于确保未来几代人拥有更清洁、更安全和更可持续的能源格局至关重要。