controlled thermonuclear research

简明释义

受控热核研究

英英释义

例句

1.The government has invested heavily in controlled thermonuclear research 受控核聚变研究 to find sustainable energy solutions.

政府在<被包裹的短语>受控核聚变研究上投入了大量资金，以寻找可持续的能源解决方案。

2.International collaborations are crucial for advancing controlled thermonuclear research 受控核聚变研究 across borders.

国际合作对推动<被包裹的短语>受控核聚变研究跨国界的发展至关重要。

3.Many universities are now offering degrees focused on controlled thermonuclear research 受控核聚变研究 to prepare the next generation of scientists.

许多大学现在提供专注于<被包裹的短语>受控核聚变研究的学位，以培养下一代科学家。

4.The conference will feature experts discussing the future of controlled thermonuclear research 受控核聚变研究 and its implications.

会议将邀请专家讨论<被包裹的短语>受控核聚变研究的未来及其影响。

5.The latest findings in controlled thermonuclear research 受控核聚变研究 could revolutionize the way we generate electricity.

在<被包裹的短语>受控核聚变研究中的最新发现可能会彻底改变我们发电的方式。

作文

Controlled thermonuclear research, or 受控热核研究, is a field of science that focuses on the development of fusion energy as a viable and sustainable source of power. Unlike traditional nuclear fission, which splits heavy atomic nuclei to release energy, thermonuclear fusion combines light nuclei, such as hydrogen isotopes, to form heavier nuclei, releasing a significant amount of energy in the process. This method of energy production has the potential to provide an almost limitless supply of energy, with minimal environmental impact compared to fossil fuels and conventional nuclear power. The promise of 受控热核研究 lies in its ability to harness the same processes that power the sun. In the sun's core, hydrogen atoms fuse under immense pressure and temperature, producing helium and releasing vast amounts of energy. Scientists aim to replicate these conditions on Earth in a controlled manner, which poses significant technical challenges. Achieving the necessary temperatures—millions of degrees Celsius—and maintaining stability within the plasma state are hurdles that researchers are actively working to overcome.One of the most prominent projects in the field of 受控热核研究 is the International Thermonuclear Experimental Reactor (ITER), located in France. ITER is a collaborative effort involving 35 countries, including the European Union, the United States, China, India, Japan, Russia, and South Korea. The goal of ITER is to demonstrate the feasibility of fusion as a large-scale and carbon-free source of energy. By creating a plasma that can sustain fusion reactions for extended periods, ITER aims to lay the groundwork for future commercial fusion reactors.The benefits of successful 受控热核研究 extend beyond just energy production. Fusion fuel, primarily derived from isotopes of hydrogen such as deuterium and tritium, is abundant and can be extracted from seawater. Furthermore, the waste produced from fusion reactions is significantly less hazardous than that from fission, and it has a much shorter radioactive lifespan. This makes fusion a more desirable option for addressing the global energy crisis while also mitigating climate change.However, the road to practical fusion energy is fraught with challenges. The technological advancements required for 受控热核研究 are still in their infancy, and the timeline for achieving a commercially viable fusion reactor is uncertain. Despite decades of research and investment, scientists have yet to achieve a net positive energy output from a fusion reaction. The complexity of the physics involved and the engineering challenges of building stable reactors that can withstand extreme conditions make this a daunting task.In conclusion, 受控热核研究 represents a frontier in energy research that holds great promise for the future. As the world grapples with the urgent need for sustainable energy solutions, the pursuit of fusion energy offers a beacon of hope. Continued investment in research and collaboration among nations will be essential to unlock the potential of fusion and to realize its benefits for future generations. If successful, 受控热核研究 could transform the global energy landscape, providing a clean, safe, and virtually limitless source of power for all of humanity.

受控热核研究是一个专注于将聚变能开发为可行且可持续的能源来源的科学领域。与传统的核裂变不同，核裂变是通过分裂重原子核释放能量，热核聚变则是通过结合轻原子核（如氢同位素）形成更重的原子核，从而释放出大量能量。这种能源生产方法有潜力提供几乎无限的能量供应，与化石燃料和传统核能相比，对环境的影响微乎其微。受控热核研究的前景在于其能够利用与太阳相同的过程。在太阳的核心，氢原子在巨大的压力和温度下发生聚变，产生氦并释放出巨大的能量。科学家们旨在以受控的方式在地球上复制这些条件，这面临着重大技术挑战。实现必要的温度（数百万摄氏度）并保持等离子体状态的稳定性是研究人员正在积极努力克服的障碍。受控热核研究领域中最著名的项目之一是国际热核实验反应堆（ITER），该项目位于法国。ITER是一个涉及35个国家的合作项目，包括欧盟、美国、中国、印度、日本、俄罗斯和韩国。ITER的目标是证明聚变作为一种大规模和无碳能源的可行性。通过创建能够长时间维持聚变反应的等离子体，ITER旨在为未来商业聚变反应堆奠定基础。成功的受控热核研究的好处不仅限于能源生产。聚变燃料主要来自氢的同位素，如氘和氚，这些资源丰富，可以从海水中提取。此外，聚变反应产生的废物比裂变反应产生的废物危害性小得多，其放射性寿命也短得多。这使得聚变成为解决全球能源危机并减缓气候变化的更可取的选择。然而，实现实际聚变能源的道路充满挑战。受控热核研究所需的技术进步仍处于起步阶段，达到可商业化聚变反应堆的时间表尚不确定。尽管经过数十年的研究和投资，科学家们仍未能从聚变反应中获得净正能量输出。涉及的物理复杂性以及建造能够承受极端条件的稳定反应堆的工程挑战，使这一任务变得艰巨。总之，受控热核研究代表了能源研究的前沿，蕴含着对未来的巨大希望。随着世界面临对可持续能源解决方案的迫切需求，追求聚变能源为我们提供了一线希望。继续投资于研究以及各国之间的合作对于释放聚变的潜力和实现其对未来几代人的利益至关重要。如果成功，受控热核研究将改变全球能源格局，为全人类提供清洁、安全和几乎无限的能源来源。