thermonuclear reactor

简明释义

热核反应堆

英英释义

例句

1.A new design for the thermonuclear reactor 热核反应堆 has been proposed by researchers at MIT.

麻省理工学院的研究人员提出了一种新的热核反应堆设计。

2.The thermonuclear reactor 热核反应堆 is expected to provide a nearly limitless source of energy.

热核反应堆预计将提供几乎无限的能源来源。

3.The development of the first practical thermonuclear reactor 热核反应堆 could revolutionize energy production.

第一个实用的热核反应堆的发展可能会彻底改变能源生产。

4.The scientists conducted experiments to improve the efficiency of the thermonuclear reactor 热核反应堆.

科学家们进行了实验，以提高热核反应堆的效率。

5.Safety protocols are crucial when operating a thermonuclear reactor 热核反应堆.

在操作热核反应堆时，安全协议至关重要。

作文

The concept of a thermonuclear reactor is pivotal in the field of nuclear physics and energy production. These reactors operate on the principle of nuclear fusion, which is the process that powers the sun and other stars. In a thermonuclear reactor, light atomic nuclei, such as isotopes of hydrogen, are fused together under extreme temperature and pressure conditions to form heavier nuclei, releasing a tremendous amount of energy in the process. This energy output is significantly greater than that produced by traditional nuclear fission reactors, which split heavy atomic nuclei apart.One of the main advantages of a thermonuclear reactor is its potential for providing a nearly limitless source of clean energy. Unlike fossil fuels, which emit greenhouse gases and contribute to climate change, fusion reactions produce minimal radioactive waste and do not release harmful emissions. This makes thermonuclear reactors an attractive option for addressing the world’s growing energy needs while simultaneously combating environmental issues.However, achieving controlled fusion in a thermonuclear reactor is a complex challenge. The extreme conditions required for fusion demand advanced technology and materials that can withstand high temperatures and pressures. Current experimental reactors, such as ITER (International Thermonuclear Experimental Reactor) in France, aim to demonstrate the feasibility of fusion as a practical energy source. Scientists are working tirelessly to overcome the technical hurdles associated with maintaining stable plasma and achieving net positive energy output from these reactors.The development of thermonuclear reactors also poses significant economic implications. While the initial investment in research and infrastructure can be substantial, the long-term benefits of a reliable and sustainable energy source could outweigh these costs. As nations grapple with energy security and the transition to renewable energy sources, thermonuclear reactors could play a vital role in the future energy landscape.Public perception of thermonuclear reactors is another important factor to consider. Many people associate nuclear energy with risks and disasters, primarily due to high-profile accidents at fission reactors. However, it is crucial to educate the public about the safety measures and advancements in fusion technology that make thermonuclear reactors inherently safer than their fission counterparts. For instance, in the event of a malfunction, a fusion reaction would naturally cease, as the conditions necessary for sustaining it would be disrupted.In conclusion, the thermonuclear reactor represents a promising frontier in energy production. With ongoing research and international collaboration, the dream of harnessing the power of the stars could become a reality, providing a sustainable and abundant energy source for generations to come. As we continue to face the challenges of climate change and energy scarcity, investing in thermonuclear reactors may very well be one of the keys to a brighter, cleaner future for our planet.

“热核反应堆”的概念在核物理和能源生产领域中至关重要。这些反应堆基于核聚变的原理，核聚变是驱动太阳和其他恒星的过程。在“热核反应堆”中，轻原子核（如氢的同位素）在极端温度和压力条件下融合成较重的原子核，并在此过程中释放出巨大的能量。这种能量输出远远大于传统核裂变反应堆产生的能量，后者是通过分裂重原子核来释放能量。“热核反应堆”的主要优点之一是其提供几乎无限清洁能源的潜力。与排放温室气体并导致气候变化的化石燃料不同，聚变反应产生的放射性废物极少且不释放有害排放物。这使得“热核反应堆”成为应对全球日益增长的能源需求，同时又能抵御环境问题的有吸引力的选择。然而，在“热核反应堆”中实现受控聚变是一项复杂的挑战。聚变所需的极端条件需要先进的技术和能够承受高温高压的材料。目前的实验性反应堆，例如位于法国的国际热核实验反应堆（ITER），旨在证明聚变作为实用能源的可行性。科学家们正在不懈努力以克服与维持稳定等离子体和实现这些反应堆正能量输出相关的技术难题。“热核反应堆”的发展也带来了重大的经济影响。虽然在研究和基础设施上的初期投资可能很大，但可靠和可持续能源来源的长期利益可能会超过这些成本。当各国应对能源安全和向可再生能源转型的问题时，“热核反应堆”可能在未来的能源格局中发挥至关重要的作用。公众对“热核反应堆”的看法也是一个重要因素。许多人将核能与风险和灾难联系在一起，主要是由于裂变反应堆的高调事故。然而，教育公众了解安全措施和聚变技术的进步，使“热核反应堆”比裂变反应堆本质上更安全是至关重要的。例如，如果发生故障，聚变反应将自然停止，因为维持聚变所需的条件将被破坏。总之，“热核反应堆”代表了能源生产中的一个有前途的前沿。随着持续的研究和国际合作，利用星星的力量的梦想可能会成为现实，为我们这一代人提供可持续和丰富的能源来源。当我们继续面临气候变化和能源短缺的挑战时，投资“热核反应堆”可能确实是我们星球更光明、更清洁未来的关键之一。