astrophysical

简明释义

英[ˌæstrəʊˈfɪzɪkl]美[ˌæstroʊˈfɪzɪkl]

adj. 天体物理学的

英英释义

单词用法

同义词

反义词

例句

1.That weather report brought to you by researchers publishing in the journal Astrophysical journal Letters.

你听到的这次天气预报，由研究人员发表在《天体物理学通讯季刊》杂志上。

2.The research will be detailed in a March issue of The Astrophysical Journal.

该项研究的详情将见于天文学报3月份文章。

3.A new piece of astrophysical research may, however, have uncovered a crucial piece of the puzzle.

然而，新领域的天体物理学研究或许已经揭示出这个谜团的关键因素。

4.Details of the discovery will be published in a forthcoming issue of the Astrophysical Journal.

此新发现的详情将在下期的《太空物理》期刊上发表。

5.Their findings will be published in the Astrophysical Journal.

他们的发现将发表在《天体物理学》杂志上。

6.The research will appear October 20 in The Astrophysical Journal.

该研究将在十月20号的天体物理学报上登出。

7.To that end, astrophysical topics are grouped according to the relevant areas of physics.

为此目的，太空物理学的题目被根据物理学的相关的领域归类。

8.That analysis was just completed and the findings were published in the newest edition of Astrophysical Journal Letters.

最近，这份分析报告才刚刚完成，并登上了最新一期的《天文物理期刊》。

9.He floats that suggestion in the Astrophysical Journal Letters.

他把这个见解发表在了《天体物理学报通信》上。

10.The study of black holes is a crucial part of modern astrophysical 天体物理学的 research.

黑洞的研究是现代天体物理学的一项关键部分。

11.Many astrophysical 天体物理学的 phenomena can be observed through powerful telescopes.

许多天体物理学的现象可以通过强大的望远镜观察到。

12.The astrophysical 天体物理学的 implications of dark matter are still being researched.

暗物质的天体物理学的影响仍在研究中。

13.Astrophysicists analyze data from various sources to understand astrophysical 天体物理学的 events like supernovae.

天体物理学家分析来自各种来源的数据，以理解像超新星这样的天体物理学的事件。

14.The astrophysical 天体物理学的 properties of stars help us learn about their life cycles.

恒星的天体物理学的特性帮助我们了解它们的生命周期。

作文

Astrophysics is a branch of astronomy that deals with the physics of celestial objects and phenomena. It combines principles of physics and chemistry to understand how stars, planets, galaxies, and the universe as a whole behave. The term astrophysical (天体物理的) is often used to describe the various processes and properties associated with these celestial bodies. For example, when we study the life cycle of a star, we delve into its astrophysical (天体物理的) characteristics such as its mass, temperature, luminosity, and chemical composition. These factors determine how a star evolves over time, from its formation in a nebula to its eventual death, which may result in a supernova or the creation of a black hole. One of the most fascinating aspects of astrophysical (天体物理的) research is the study of black holes. These mysterious entities are formed when massive stars collapse under their own gravity, leading to a region in space where the gravitational pull is so strong that nothing, not even light, can escape. Understanding the astrophysical (天体物理的) properties of black holes is crucial for comprehending the fundamental laws of physics, including general relativity and quantum mechanics. Scientists use advanced techniques, such as gravitational wave detection and electromagnetic observations, to investigate these enigmatic structures. Another significant area of astrophysical (天体物理的) research is the study of dark matter and dark energy. While ordinary matter makes up stars, planets, and living organisms, dark matter is an unseen substance that exerts gravitational forces on visible matter, influencing the structure and evolution of the universe. Dark energy, on the other hand, is a mysterious force that is causing the accelerated expansion of the universe. Both of these components are essential for a complete understanding of the astrophysical (天体物理的) framework of our cosmos. In addition to these phenomena, astrophysical (天体物理的) studies also encompass the exploration of exoplanets—planets located outside our solar system. With the advent of powerful telescopes and detection methods, scientists have discovered thousands of exoplanets, some of which may harbor conditions suitable for life. By analyzing the astrophysical (天体物理的) characteristics of these distant worlds, researchers hope to answer profound questions about the existence of life beyond Earth. The field of astrophysical (天体物理的) research is not only intellectually stimulating but also holds practical implications for humanity. Understanding the origins of the universe and our place within it can inspire future generations to pursue careers in science, technology, engineering, and mathematics (STEM). Furthermore, advancements in astrophysical (天体物理的) knowledge can lead to technological innovations that benefit society, such as improvements in imaging technology and materials science. In conclusion, the study of astrophysical (天体物理的) phenomena provides insights into the fundamental workings of the universe. From the lifecycle of stars to the mysteries of black holes and the nature of dark matter, astrophysics challenges our understanding of reality and pushes the boundaries of human knowledge. As we continue to explore the cosmos, the importance of astrophysical (天体物理的) research will only grow, revealing the intricate tapestry of the universe and our connection to it.

天体物理学是一个研究天体及其现象的天文学分支。它结合了物理学和化学的原理，以理解恒星、行星、星系以及整个宇宙的行为。术语astrophysical（天体物理的）通常用于描述与这些天体相关的各种过程和特性。例如，当我们研究恒星的生命周期时，我们深入探讨其astrophysical（天体物理的）特征，如质量、温度、光度和化学成分。这些因素决定了恒星随时间的演变，从在星云中的形成到最终死亡，这可能导致超新星或黑洞的产生。 astrophysical（天体物理的）研究中最迷人的方面之一是对黑洞的研究。这些神秘的实体是在大质量恒星在自身引力下坍缩时形成的，导致在空间中出现一个区域，其引力如此强大，以至于没有任何东西，包括光，都能逃脱。理解黑洞的astrophysical（天体物理的）特性对于理解物理学的基本法则至关重要，包括广义相对论和量子力学。科学家们使用先进的技术，如引力波探测和电磁观测，来研究这些神秘的结构。 astrophysical（天体物理的）研究的另一个重要领域是暗物质和暗能量的研究。虽然普通物质构成了恒星、行星和生物，但暗物质是一种看不见的物质，对可见物质施加引力，影响宇宙的结构和演变。另一方面，暗能量是一种神秘的力量，正在导致宇宙的加速膨胀。这两个组成部分对于完整理解astrophysical（天体物理的）框架至关重要。 除了这些现象，astrophysical（天体物理的）研究还包括对系外行星的探索——位于我们太阳系之外的行星。随着强大望远镜和探测方法的出现，科学家们发现了数千个系外行星，其中一些可能具备适合生命存在的条件。通过分析这些遥远世界的astrophysical（天体物理的）特征，研究人员希望回答关于地球以外生命存在的深刻问题。 astrophysical（天体物理的）研究领域不仅在智力上令人兴奋，而且对人类也有实际意义。理解宇宙的起源和我们在其中的位置可以激励未来几代人追求科学、技术、工程和数学（STEM）领域的职业。此外，astrophysical（天体物理的）知识的进步可以带来有益于社会的技术创新，例如成像技术和材料科学的改进。 总之，研究astrophysical（天体物理的）现象为我们提供了对宇宙基本运作方式的洞察。从恒星的生命周期到黑洞的奥秘，再到暗物质的本质，天体物理学挑战着我们对现实的理解，并推动人类知识的边界。随着我们继续探索宇宙，astrophysical（天体物理的）研究的重要性只会增加，揭示宇宙的复杂织锦以及我们与之的联系。