thermonuclear electric cell
简明释义
热核电池
英英释义
A thermonuclear electric cell is a type of energy conversion device that utilizes the energy released from thermonuclear reactions to generate electricity. | 热核电池是一种利用热核反应释放的能量来产生电力的能量转换装置。 |
例句
1.The military is exploring the use of thermonuclear electric cells for powering advanced weapon systems.
军方正在探索使用热核电池为先进武器系统供电。
2.Researchers are studying the efficiency of the thermonuclear electric cell to improve energy output in future applications.
研究人员正在研究热核电池的效率,以提高未来应用中的能量输出。
3.In a recent conference, scientists presented their findings on the potential of thermonuclear electric cells in reducing carbon emissions.
在最近的会议上,科学家们展示了热核电池在减少碳排放方面的潜力。
4.A prototype car has been developed that runs on a thermonuclear electric cell, aiming for zero emissions.
一款原型车已经开发出来,使用热核电池运行,目标是零排放。
5.The new spaceship is powered by a thermonuclear electric cell, which provides a sustainable energy source for long missions.
这艘新飞船由热核电池供电,为长期任务提供可持续的能源来源。
作文
In recent years, the quest for sustainable and efficient energy sources has led scientists to explore various innovative technologies. One such advancement is the development of the thermonuclear electric cell (热核电池), which promises to revolutionize how we harness energy. This technology combines principles of thermonuclear fusion with electrical generation, aiming to provide a clean, virtually limitless power source. Unlike traditional nuclear reactors, which rely on fission, the thermonuclear electric cell utilizes the process of fusion, where light atomic nuclei combine to form heavier nuclei, releasing vast amounts of energy in the process.The concept of fusion has been around for decades, primarily explored in the context of stars, including our sun. In these celestial bodies, extreme temperatures and pressures enable hydrogen atoms to fuse, generating enormous energy. Scientists have long sought to replicate this process on Earth, but the challenges have been significant. However, advancements in materials science and plasma physics have brought us closer to realizing practical applications of fusion energy.The thermonuclear electric cell operates by creating conditions similar to those found in stars. It involves heating a fuel, typically isotopes of hydrogen like deuterium and tritium, to extremely high temperatures, allowing them to overcome their natural repulsion due to electrostatic forces. Once fused, these isotopes release neutrons and energy, which can then be converted into electricity through various methods, such as heating a fluid to drive turbines or using thermoelectric generators.One of the most significant advantages of the thermonuclear electric cell is its potential for safety and sustainability. Unlike fossil fuels, which emit greenhouse gases and contribute to climate change, fusion produces minimal waste and does not release harmful emissions. Additionally, the fuel for fusion—hydrogen—is abundant and can be extracted from water, making it a renewable resource. This aspect addresses one of the critical challenges of our time: the need for clean energy solutions that can support growing global demands without harming the environment.Moreover, the thermonuclear electric cell offers the possibility of providing energy on a massive scale. Current estimates suggest that a single fusion reaction can produce millions of times more energy than a chemical reaction, such as burning coal or gas. This efficiency could lead to lower energy costs and greater energy security for nations worldwide.Despite these promising attributes, the road to widespread adoption of the thermonuclear electric cell is fraught with challenges. The technology is still in its experimental stages, and significant investments are required to develop it further. Researchers must overcome technical hurdles related to containment, stability, and energy conversion efficiency. Furthermore, public perception and regulatory frameworks surrounding nuclear technology will also play a crucial role in determining the future of fusion energy.In conclusion, the thermonuclear electric cell represents a groundbreaking step towards sustainable energy production. By mimicking the processes that power the stars, this technology holds the promise of providing clean, efficient, and virtually limitless energy. As research continues and technological advancements are made, we may soon see the thermonuclear electric cell transitioning from theoretical concepts to practical applications, paving the way for a brighter, more sustainable future for generations to come.
近年来,寻找可持续和高效的能源来源促使科学家探索各种创新技术。其中一个进展是开发热核电池(thermonuclear electric cell),它有望彻底改变我们获取能源的方式。这项技术结合了热核聚变的原理与电力生成,旨在提供一种清洁、几乎无限的能源来源。与传统的核反应堆依赖裂变不同,热核电池利用的是聚变过程,在该过程中,轻原子核结合形成重核,从而释放出大量能量。聚变的概念已经存在几十年,主要是在恒星(包括我们的太阳)的背景下进行探索。在这些天体中,极高的温度和压力使氢原子能够融合,产生巨大的能量。科学家们一直试图在地球上复制这一过程,但面临的挑战非常重大。然而,材料科学和等离子体物理学的进步使我们更接近于实现聚变能源的实际应用。热核电池通过创造类似于恒星内部的条件来运作。它涉及将燃料(通常是氢的同位素如氘和氚)加热到极高的温度,使其克服由于静电力造成的自然排斥。一旦融合,这些同位素就会释放出中子和能量,这些能量可以通过多种方法转化为电力,例如加热流体以驱动涡轮机或使用热电发电机。热核电池最显著的优势之一是它在安全性和可持续性方面的潜力。与化石燃料不同,化石燃料会排放温室气体并导致气候变化,聚变产生的废物极少且不会释放有害排放。此外,聚变的燃料——氢,是丰富的,可以从水中提取,这使其成为一种可再生资源。这一方面解决了我们时代面临的一个关键挑战:需要清洁能源解决方案,以支持全球日益增长的需求,而不损害环境。此外,热核电池还提供了大规模提供能源的可能性。目前的估计表明,单个聚变反应可以产生比化学反应(如燃烧煤或天然气)多数百万倍的能量。这种效率可能导致能源成本降低,并为全球各国提供更大的能源安全。尽管有这些令人鼓舞的特性,热核电池的广泛采用之路充满挑战。这项技术仍处于实验阶段,需要大量投资来进一步开发。研究人员必须克服与约束、稳定性和能量转换效率相关的技术难题。此外,公众对核技术的看法和监管框架也将在决定聚变能源未来方面发挥至关重要的作用。总之,热核电池代表了朝着可持续能源生产迈出的突破性一步。通过模仿驱动恒星的过程,这项技术承诺提供清洁、高效和几乎无限的能源。随着研究的继续和技术的进步,我们可能很快会看到热核电池从理论概念转变为实际应用,为未来几代人铺平更加光明和可持续的道路。
相关单词
