globular
简明释义
adj. 球状的;由小球形成的;闻名世界的
英英释义
Having a shape that is spherical or rounded; resembling a globe. | 具有球形或圆形的形状;类似于地球仪。 |
与小球体或小球状物体有关的。 |
单词用法
球状星团 |
同义词
| 球形的 | 地球并不是一个完美的球体,而是一个扁球体。 | ||
| 圆的 | 她把花放在一个圆形的花瓶里。 | ||
| 圆形的 | 月亮在夜空中看起来是圆形的。 | ||
| 球状的 | 这种植物有球状的根部储存水分。 |
反义词
例句
1.When you've got two million stars to gawk at, not much else needs to be said, except this shows only one-fifth of the stars in this globular cluster.
当你看到有将近两百万星星在围观自己,再多的话也不知从何说起。还要告诉你的是,它们仅仅占了此球状星团的五分之一。
2.There are two main groups of proteins: globular proteins and fibrous proteins.
有两种类型的蛋白质:球蛋白和纤维蛋白。
3.Studying globular clusters therefore tells us about the history of our galaxy.
因此,研究球状星团可以向我们揭示银河系的历史。
4.Globular clusters have some of the oldest stars in the universe.
球状星团中有很多宇宙中最古老的恒星。
5.Different plants depict stars, globular clusters, and even nebulas.
不同的植物描绘出恒星、球状星团,甚至还有星云。
6.Globular clusters once ruled the Milky Way.
球状星团曾经统治着银河系。
7.The spectrum reveals emission from oxygen and nitrogen but no hydrogen, a rare set of signals from within globular clusters.
频谱显示出氧和氮,但没有氢,一个球状星团内罕见的信号。
8.The scientist observed a globular 球状的 cluster of stars through the telescope.
科学家通过望远镜观察到一个球状的球状的星团。
9.In biology class, we studied globular 球状的 proteins and their functions in the cell.
在生物课上,我们研究了球状的球状的蛋白质及其在细胞中的功能。
10.The globular 球状的 design of the lamp adds a modern touch to the room.
这个灯具的球状的球状的设计为房间增添了现代感。
11.The artist created a sculpture that featured several globular 球状的 forms.
艺术家创作了一座雕塑,里面有几个球状的球状的形状。
12.The jelly had a globular 球状的 shape that made it visually appealing on the plate.
果冻呈现出一个球状的球状的形状,使其在盘子上看起来很吸引人。
作文
In the realm of science, particularly in physics and astronomy, the term globular (球形的) is often used to describe objects that have a spherical shape. This characteristic is not merely aesthetic; it has significant implications for the properties and behaviors of these objects. For instance, planets, stars, and many celestial bodies exhibit a globular (球形的) form due to the force of gravity pulling matter towards a central point, resulting in a shape that minimizes surface area for a given volume. This phenomenon can be observed in our own Earth, which is not a perfect sphere but an oblate spheroid, slightly flattened at the poles and bulging at the equator.The concept of globular (球形的) shapes extends beyond celestial bodies. In biology, many microorganisms, such as certain bacteria, are globular (球形的) in appearance. The globular (球形的) structure of these organisms plays a crucial role in their function and survival. For example, the round shape can help reduce drag as they move through liquids, allowing for more efficient locomotion. Additionally, the globular (球形的) configuration can facilitate the absorption of nutrients, as the surface area relative to volume is maximized for smaller organisms.Moreover, the study of globular (球形的) clusters in astronomy has provided insights into the formation and evolution of galaxies. These clusters are densely packed groups of stars that exhibit a globular (球形的) arrangement, and they are believed to be among the oldest structures in the universe. The gravitational interactions within these globular (球形的) clusters can lead to fascinating phenomena, such as the formation of new stars and the dynamics of stellar evolution.In the field of materials science, the properties of globular (球形的) particles are of great interest. Researchers often study how the globular (球形的) arrangement of particles can influence the mechanical properties of materials. For instance, globular (球形的) metal powders are commonly used in additive manufacturing processes, where their shape can affect the flowability and packing density of the material during printing. Understanding the behavior of globular (球形的) particles is essential for optimizing the production of high-performance materials.In conclusion, the term globular (球形的) encompasses a wide array of applications across various scientific disciplines. From the cosmos to the microscopic world, the significance of globular (球形的) shapes cannot be overstated. They not only represent fundamental principles of physics and biology but also play a vital role in technological advancements. As we continue to explore and understand the universe around us, the study of globular (球形的) forms will undoubtedly remain a key area of research, illuminating the intricate connections between shape, function, and the laws of nature.
在科学领域,尤其是物理学和天文学中,术语globular(球形的)通常用于描述具有球形的物体。这一特征不仅仅是美观的,它对这些物体的性质和行为有重要影响。例如,行星、恒星和许多天体由于重力将物质拉向中心点,因此呈现出globular(球形的)形状,这导致在给定体积下最小化表面积。这种现象可以在我们自己的地球上观察到,地球并不是一个完美的球体,而是一个扁球体,在极地略微扁平,在赤道隆起。globular(球形的)形状的概念超越了天体。在生物学中,许多微生物,如某些细菌,呈现出globular(球形的)外观。这些生物的globular(球形的)结构在其功能和生存中发挥着至关重要的作用。例如,圆形可以帮助减少它们在液体中的阻力,从而实现更高效的运动。此外,globular(球形的)配置可以促进营养物质的吸收,因为相对于体积,表面积在较小生物中得到了最大化。此外,天文学中对globular(球形的)星团的研究为银河系的形成和演化提供了见解。这些星团是密集的恒星群,呈现出globular(球形的)排列,被认为是宇宙中最古老的结构之一。星团内的引力相互作用可能导致迷人的现象,例如新恒星的形成和恒星演化的动态。在材料科学领域,globular(球形的)颗粒的性质备受关注。研究人员经常研究globular(球形的)颗粒的排列如何影响材料的机械性能。例如,globular(球形的)金属粉末通常用于增材制造过程,其中它们的形状可以影响材料在打印过程中的流动性和堆积密度。理解globular(球形的)颗粒的行为对优化高性能材料的生产至关重要。总之,术语globular(球形的)涵盖了各个科学学科中的广泛应用。从宇宙到微观世界,globular(球形的)形状的重要性不容小觑。它们不仅代表了物理学和生物学的基本原理,还在技术进步中发挥着重要作用。随着我们继续探索和理解周围的宇宙,对globular(球形的)形态的研究无疑将仍然是一个关键的研究领域,揭示形状、功能与自然法则之间的复杂联系。
