radiogenic

简明释义

英[ˌreɪdiəʊˈdʒenɪk]美[ˌreɪdioʊˈdʒenɪk]

adj. 适于无线电广播的；[核] 放射产生的

英英释义

单词用法

同义词

反义词

例句

1.The radiogenic heat production rate in the upper crust decreased with the increasing depth. However, they were distributed uniformly within the depth scale of sedimentary basin.

岩石生热率在上地壳的分布是随深度的增加而减小的，但在沉积盆地的深度范围内几乎不变，其分布是均匀的，仅不同岩性的生热率差别较大。

2.Water tank ultra violet ray insect lamp . diaphram strainer anti osmosis treatment kitchen equipmcm laundry equipment radiogenic waste water treatment.

菌器薄膜过泸器逆渗透处理厨房设备洗衣房设备放射性废水处理。

3.Cancers induced by ionizing radiation are called radiogenic cancers or radiogenic neoplasms.

电离辐射诱发的癌症称为放射性癌症或放射性肿瘤。

4.The Earth has cooled since its formation, yet the decay of radiogenic isotopes, and in particular uranium, thorium and potassium, in the planet's interior provides a continuing heat source.

研究人员发现，在地球传送到大气的热流中，地球内部放射性同位素衰变所产生的热量占了其中一半。

5.Using data gathered from other sources on potassium-the other major element-they were able to estimate that radiogenic heat accounts for half of the heat produced by the Earth.

使用从其他来源收集到的钾(另一种主要元素)的数据，放射热估计能够占地球产生的热量的一半。

6.Radiogenic heat, even from a fairly deep-seated uranium orebody, could be measured.

即使铀矿体埋得足够深，它的放射成因热也能被测出。

7.Environmental studies often focus on radiogenic 放射源的 contamination in soil and water.

环境研究通常关注土壤和水中的放射源的放射源的污染。

8.The presence of radiogenic 放射源的 elements can indicate past volcanic activity.

存在放射源的放射源的元素可能表明过去的火山活动。

9.Geologists use radiogenic 放射源的 dating methods to reconstruct the history of Earth.

地质学家使用放射源的放射源的年代测定方法来重建地球的历史。

10.The rocks in this area are known to be radiogenic 放射源的, which means they contain minerals that emit radiation.

该地区的岩石被认为是放射源的放射源的，这意味着它们含有会发出辐射的矿物。

11.Scientists study radiogenic 放射源的 isotopes to determine the age of geological formations.

科学家研究放射源的放射源的同位素以确定地质构造的年龄。

作文

The term radiogenic refers to materials or elements that are produced by the decay of radioactive isotopes. This concept is particularly significant in fields such as geology, archaeology, and environmental science. Understanding radiogenic processes allows scientists to trace the origins of various minerals and to date ancient artifacts. For instance, the use of radiogenic isotopes like uranium-238 and lead-206 has revolutionized our ability to determine the age of rocks and fossils, providing insights into the history of our planet. One of the most fascinating applications of radiogenic dating is in the study of meteorites. By analyzing the radiogenic isotopes found within these cosmic rocks, researchers can gain valuable information about the early solar system. The isotopic ratios reveal how long the meteorites have been in existence and provide clues about the conditions present during their formation. Such studies not only enhance our understanding of planetary formation but also offer a glimpse into the history of our own Earth.In addition to geological studies, the concept of radiogenic materials plays a crucial role in the field of medicine, particularly in cancer treatment. Radioactive isotopes are often used in targeted therapies to destroy cancer cells while minimizing damage to surrounding healthy tissue. This radiogenic approach has proven effective in treating various types of cancer, showcasing the potential benefits of harnessing radioactive materials for therapeutic purposes.However, the use of radiogenic materials is not without its challenges. The potential health risks associated with exposure to radiation necessitate strict regulations and safety protocols. Scientists must carefully monitor the levels of radiogenic substances to ensure that they do not pose a threat to human health or the environment. This balance between utilizing radiogenic materials for advancement in science and medicine while safeguarding public health is a critical aspect of ongoing research and development.Moreover, the study of radiogenic isotopes extends beyond Earth. Astrobiologists are particularly interested in the potential for radiogenic elements to support life on other planets. The presence of certain isotopes could indicate geological activity, which is essential for sustaining life. By examining the radiogenic signatures of other celestial bodies, scientists hope to uncover whether life exists beyond our planet.In conclusion, the term radiogenic encapsulates a wide array of scientific phenomena, from dating ancient rocks to advancing medical treatments. As our understanding of radiogenic processes continues to evolve, so too does our ability to explore the universe and improve human health. The implications of radiogenic research are vast and varied, highlighting the importance of this concept in both scientific inquiry and practical applications. Whether in the realm of geology, medicine, or astrobiology, the study of radiogenic materials remains a pivotal area of exploration, promising new discoveries and innovations for the future.

“放射性生成”一词指的是由放射性同位素衰变产生的材料或元素。这个概念在地质学、考古学和环境科学等领域尤其重要。理解“放射性生成”过程使科学家能够追踪各种矿物的起源，并对古代文物进行年代测定。例如，使用铀-238和铅-206等“放射性生成”同位素的技术彻底改变了我们确定岩石和化石年龄的能力，为我们提供了有关地球历史的深刻见解。“放射性生成”年代测定最引人入胜的应用之一是在陨石研究中。通过分析这些宇宙岩石中的“放射性生成”同位素，研究人员可以获得关于早期太阳系的宝贵信息。同位素比率揭示了陨石存在的时间长短，并提供了有关其形成时条件的线索。这种研究不仅增强了我们对行星形成的理解，还为我们自身地球的历史提供了一瞥。除了地质研究外，“放射性生成”材料的概念在医学领域也发挥着至关重要的作用，尤其是在癌症治疗中。放射性同位素常用于靶向疗法，以摧毁癌细胞，同时尽量减少对周围健康组织的损害。这种“放射性生成”方法在治疗各种类型的癌症中被证明是有效的，展示了利用放射性材料进行治疗的潜在好处。然而，使用“放射性生成”材料并非没有挑战。暴露于辐射所带来的潜在健康风险需要严格的法规和安全协议。科学家必须仔细监测“放射性生成”物质的水平，以确保它们不会对人类健康或环境构成威胁。在科学和医学进步与保护公共健康之间取得这种平衡是持续研究和发展的关键方面。此外，“放射性生成”同位素的研究超越了地球。天体生物学家特别关注“放射性生成”元素在其他行星上支持生命的潜力。某些同位素的存在可能表明地质活动，而这对于维持生命至关重要。通过检查其他天体的“放射性生成”特征，科学家希望揭示生命是否存在于我们星球之外。总之，“放射性生成”一词涵盖了广泛的科学现象，从对古老岩石的年代测定到推动医学治疗。随着我们对“放射性生成”过程的理解不断发展，我们探索宇宙和改善人类健康的能力也在不断提升。“放射性生成”研究的意义广泛而多样，突显了这一概念在科学探究和实际应用中的重要性。无论是在地质学、医学还是天体生物学领域，对“放射性生成”材料的研究仍然是一个关键的探索领域，承诺为未来带来新的发现和创新。