nucleonics

简明释义

英[ˌnjuːklɪˈɒnɪks]美[ˌnjʊklɪˈɑnɪks]

n. 核子学；原子核物理学

英英释义

单词用法

同义词

反义词

例句

1.NBC News crew members in Japan are using radiation detectors from Berkeley Nucleonics that they can wear on their belts, much like beepers.

NBC新闻在日本的员工正在使用BerkeleyNucleonics生产的探测器，就是像寻呼机一样可以挂在腰上的那种。

2.NBC News crew members in Japan are using radiation detectors from Berkeley Nucleonics that they can wear on their belts, much like beepers.

NBC新闻在日本的员工正在使用BerkeleyNucleonics生产的探测器，就是像寻呼机一样可以挂在腰上的那种。

3.The field of nucleonics is crucial for developing new energy sources.

领域的核能学对于开发新的能源来源至关重要。

4.Many universities offer specialized courses in nucleonics to prepare students for careers in nuclear science.

许多大学提供专门的核能学课程，以为学生准备核科学职业。

5.Research in nucleonics has led to significant advancements in medical imaging technologies.

在核能学方面的研究已经导致医学成像技术的重大进步。

6.The safety protocols in nucleonics are strictly regulated to prevent accidents.

在核能学中的安全协议受到严格监管，以防止事故。

7.Understanding the principles of nucleonics is essential for anyone working in the nuclear power industry.

理解核能学的原理对于在核电行业工作的任何人都是必不可少的。

作文

Nucleonics is a fascinating field of study that focuses on the behavior and properties of atomic nuclei. It plays a crucial role in various aspects of modern science and technology, particularly in areas such as nuclear energy, medicine, and security. The term 'nucleonics' refers to the branch of physics that deals with the interactions and reactions of atomic nuclei, which are the core components of atoms. Understanding these interactions is essential for harnessing nuclear energy and developing advanced technologies that rely on nuclear reactions. One of the most significant applications of nucleonics (核物理学) is in the production of nuclear energy. Nuclear power plants utilize the process of nuclear fission, where the nucleus of an atom splits into smaller parts, releasing a tremendous amount of energy. This energy can then be converted into electricity, providing a powerful and efficient source of energy for millions of people worldwide. The study of nucleonics (核物理学) allows scientists and engineers to optimize the design and operation of these power plants, ensuring they operate safely and efficiently. In addition to energy production, nucleonics (核物理学) also has significant implications in the field of medicine. Nuclear medicine uses radioactive isotopes for diagnosis and treatment of various diseases. For instance, positron emission tomography (PET) scans rely on the principles of nucleonics (核物理学) to visualize metabolic processes in the body. By understanding the behavior of radioactive materials at the nuclear level, medical professionals can develop targeted therapies that minimize side effects and improve patient outcomes. Furthermore, nucleonics (核物理学) plays a vital role in national security. The detection and monitoring of nuclear materials are essential for preventing the proliferation of nuclear weapons and ensuring global safety. Technologies developed through nucleonics (核物理学) research enable governments to detect illicit nuclear activities and respond effectively to potential threats. This aspect of nucleonics (核物理学) highlights its importance not only in scientific advancement but also in maintaining international peace and security. As we delve deeper into the realm of nucleonics (核物理学), we uncover the potential for new discoveries and innovations. Research in this field is continually evolving, leading to advancements in reactor design, waste management, and even fusion energy—a cleaner and more sustainable alternative to traditional nuclear power. The pursuit of knowledge in nucleonics (核物理学) has the potential to address some of the most pressing challenges facing humanity, including energy shortages and environmental concerns. In conclusion, nucleonics (核物理学) is a critical area of study that encompasses a wide range of applications from energy production to medical advancements and national security. Its impact on our lives is profound, shaping the way we understand and interact with the world. As we continue to explore the intricacies of atomic nuclei, the possibilities for innovation and improvement in various fields are limitless. Embracing the knowledge and advancements in nucleonics (核物理学) will undoubtedly lead us toward a brighter and more sustainable future.

核物理学是一个引人入胜的研究领域，专注于原子核的行为和性质。它在现代科学和技术的各个方面发挥着至关重要的作用，特别是在核能、医学和安全等领域。“核物理学”这个术语指的是处理原子核相互作用和反应的物理学分支。理解这些相互作用对于利用核能和开发依赖于核反应的先进技术至关重要。 核物理学在核能生产中的应用尤为重要。核电站利用核裂变的过程，即原子核分裂成更小的部分，释放出大量的能量。这种能量可以转化为电力，为全球数百万人提供强大而高效的能源来源。核物理学的研究使科学家和工程师能够优化这些电厂的设计和运行，确保它们安全高效地运作。 除了能源生产，核物理学在医学领域也具有重要意义。核医学利用放射性同位素来诊断和治疗各种疾病。例如，正电子发射断层扫描（PET）依赖于核物理学的原理来可视化身体的代谢过程。通过理解放射性材料在核级别的行为，医疗专业人员可以开发针对性的治疗方法，最大限度地减少副作用，提高患者的治疗效果。 此外，核物理学在国家安全中也发挥着至关重要的作用。检测和监测核材料对于防止核武器扩散和确保全球安全至关重要。通过核物理学研究开发的技术使各国政府能够检测非法核活动并有效应对潜在威胁。这一方面强调了核物理学不仅在科学进步中的重要性，也在维护国际和平与安全中的重要性。 随着我们深入探索核物理学的领域，我们揭示了新发现和创新的潜力。该领域的研究不断发展，导致反应堆设计、废物管理甚至聚变能源的进步——这是一种比传统核能更清洁、更可持续的替代方案。在核物理学知识的追求中，有潜力解决人类面临的一些最紧迫的挑战，包括能源短缺和环境问题。 总之，核物理学是一个关键的研究领域，涵盖了从能源生产到医学进步和国家安全的广泛应用。它对我们生活的影响深远，塑造了我们理解和与世界互动的方式。随着我们继续探索原子核的复杂性，在各个领域的创新和改进的可能性是无限的。拥抱核物理学的知识和进步无疑将引领我们走向更加光明和可持续的未来。