radioactive battery

简明释义

原子电池

英英释义

例句

1.Researchers are developing new technologies to improve the efficiency of radioactive batteries for medical devices.

研究人员正在开发新技术，以提高用于医疗设备的放射性电池的效率。

2.The space probe was powered by a radioactive battery, which provided energy for years without the need for replacement.

这款太空探测器由一个放射性电池供电，提供了多年的能量而无需更换。

3.The concept of a radioactive battery is gaining popularity in the field of renewable energy.

在可再生能源领域，放射性电池的概念越来越受欢迎。

4.The radioactive battery used in this pacemaker ensures it can last for over a decade.

这个心脏起搏器中使用的放射性电池确保其可以持续超过十年。

5.In remote locations, radioactive batteries can provide a reliable power source for scientific instruments.

在偏远地区，放射性电池可以为科学仪器提供可靠的电源。

作文

In the world of energy production, innovation is key to meeting the growing demands of modern society. One fascinating development in this field is the concept of the radioactive battery, which utilizes radioactive isotopes to generate electricity. This technology, while still in its infancy compared to traditional batteries, has the potential to revolutionize how we think about power sources, especially for applications that require long-lasting energy without frequent recharging. A radioactive battery (放射性电池) works by harnessing the decay of radioactive materials to produce a steady flow of electrical energy. Unlike conventional batteries that rely on chemical reactions, these batteries exploit the natural process of radioactive decay, which occurs at a predictable rate over time. This means that a radioactive battery can provide a continuous power supply for years, or even decades, without the need for replacement. This feature makes them particularly appealing for use in remote locations or in devices where regular maintenance is impractical.The applications of radioactive batteries are broad and varied. For instance, they have been used in space exploration, powering satellites and space probes that travel far from the sun, where solar panels would be ineffective. The reliability and longevity of radioactive batteries make them ideal for such missions, as they can function in extreme conditions without the need for human intervention. Moreover, they are also being explored for use in medical devices, such as pacemakers, where a long-lasting power source is crucial for patient care.However, despite their advantages, the use of radioactive batteries raises important safety and ethical considerations. The handling and disposal of radioactive materials must be managed carefully to prevent environmental contamination and health risks. Regulatory frameworks are necessary to ensure that these batteries are produced, used, and disposed of safely. Additionally, public perception of nuclear technology can influence the acceptance of radioactive batteries. Education and transparency about the safety measures in place are essential to fostering trust in this technology.As research continues, scientists are exploring ways to improve the efficiency and safety of radioactive batteries. Innovations such as using less harmful isotopes or developing better shielding techniques could enhance their appeal and usability. The potential for radioactive batteries to provide sustainable energy solutions is immense, and as technology advances, we may see a shift in how energy is produced and consumed across various sectors.In conclusion, the radioactive battery (放射性电池) represents a promising frontier in energy technology. Its ability to deliver long-lasting power without the need for frequent replacements positions it as a viable alternative in specific applications, particularly where traditional energy sources fall short. As we navigate the challenges and opportunities presented by this innovative technology, it will be crucial to balance the benefits of radioactive batteries with the necessary safety and ethical considerations. With continued research and development, we may soon witness a greater integration of radioactive batteries into our energy landscape, paving the way for a more efficient and sustainable future.

在能源生产的世界中，创新是满足现代社会日益增长需求的关键。在这个领域，一个引人注目的发展是放射性电池的概念，它利用放射性同位素来产生电力。这项技术虽然相比传统电池仍处于初期阶段，但有潜力彻底改变我们对电源的看法，特别是在需要长时间供电而无需频繁充电的应用场合。放射性电池（radioactive battery）通过利用放射性材料的衰变来产生稳定的电流。与依赖化学反应的传统电池不同，这些电池利用放射性衰变的自然过程，该过程以可预测的速率随时间发生。这意味着放射性电池可以在多年甚至几十年内提供持续的电力供应，而无需更换。这一特性使它们在偏远地区或设备需要定期维护不切实际的情况下尤为吸引人。放射性电池的应用广泛而多样。例如，它们已被用于太空探索，为远离太阳的卫星和宇宙探测器提供动力，在那里太阳能电池板将无效。放射性电池的可靠性和持久性使其非常适合这种任务，因为它们可以在极端条件下运作，而无需人工干预。此外，它们还被探索用于医疗设备，例如起搏器，在这些设备中，持久的电源对于患者护理至关重要。然而，尽管具有优势，使用放射性电池也引发了重要的安全和伦理考虑。必须小心处理和处置放射性材料，以防止环境污染和健康风险。需要监管框架以确保这些电池的生产、使用和处置是安全的。此外，公众对核技术的看法可能会影响放射性电池的接受度。关于安全措施的教育和透明度对于促进对这项技术的信任至关重要。随着研究的继续，科学家们正在探索提高放射性电池效率和安全性的方法。诸如使用危害较小的同位素或开发更好的屏蔽技术等创新可能会增强其吸引力和可用性。放射性电池提供可持续能源解决方案的潜力巨大，随着技术的进步，我们可能会看到各个领域的能源生产和消费方式发生转变。总之，放射性电池（radioactive battery）代表了能源技术的一个有前途的前沿。它能够在无需频繁更换的情况下提供持久的电力，使其在特定应用中成为可行的替代方案，特别是在传统能源来源不足的地方。随着我们应对这一创新技术所带来的挑战和机遇，平衡放射性电池的好处与必要的安全和伦理考虑将至关重要。随着持续的研究和开发，我们可能很快就会看到放射性电池在我们的能源格局中更大程度的整合，为更高效和可持续的未来铺平道路。