superluminal

简明释义

英[ˌsuːpərˈluːmɪnəl]美[ˌsuːpərˈluːmɪnəl]

adj. 超光速的

英英释义

单词用法

同义词

反义词

例句

1.Be like again, Einstein's most can understand and accept but real "quantum entanglement" phenomenon, in fact it is a kind of "distance" type of material superluminal movement.

再如，爱因斯坦最不能理解和接受但却真实存在的“量子纠缠”现象，其实正是一种“超距”式的物质超光速运动。

2.Be like again, Einstein's most can understand and accept but real "quantum entanglement" phenomenon, in fact it is a kind of "distance" type of material superluminal movement.

再如，爱因斯坦最不能理解和接受但却真实存在的“量子纠缠”现象，其实正是一种“超距”式的物质超光速运动。

3.Photonic crystal negative refractive index materials superluminal and subluminal phenomena partially coherent light laser physics and interaction between light and matter.

光子晶体，负折射率材料，超快、超慢现象，部分相干光学，激光物理，光与物质的相互作用等。

4.The structural variations and superluminal motion within some QSSs and AGNs are considered as one of the most important astrophysical phenomena revealed by VLBI.

类星体和活动星系核结构的变化及其中的视超光速运动，被认为是用VLBI方法所揭示的最重大的天体物理现象之一。

5.Recent experiments have reported superluminal 超光速 effects in certain quantum systems.

最近的实验报告显示某些量子系统中存在超光速效应。

6.In theoretical physics, certain particles are proposed to move at superluminal 超光速 speeds.

在理论物理学中，某些粒子被提议以超光速移动。

7.The concept of superluminal 超光速 travel has fascinated scientists for decades.

超光速旅行的概念几十年来一直吸引着科学家。

8.The idea of superluminal 超光速 travel raises questions about causality in physics.

超光速旅行的想法引发了关于物理学中因果关系的问题。

9.Some theories suggest that superluminal 超光速 communication could be possible using wormholes.

一些理论建议可以通过虫洞实现超光速通信。

作文

In the realm of physics, the concept of speed is often associated with our everyday experiences. We can easily relate to the speed of a car or an airplane. However, when we delve into the universe's mysteries, we encounter a term that challenges our understanding of speed: superluminal. This term refers to speeds that exceed the speed of light in a vacuum, which is approximately 299,792 kilometers per second. To grasp the implications of superluminal travel, we must first understand the significance of light speed in the fabric of spacetime.The theory of relativity, proposed by Albert Einstein, established that nothing can travel faster than light. This principle has profound implications for our understanding of the universe. For instance, if something were to achieve superluminal speeds, it would theoretically allow for time travel or instantaneous communication across vast distances. Imagine sending a message to a friend on another galaxy and receiving a response before you even finish your coffee! Such possibilities are tantalizing but also lead to paradoxes and challenges in physics.One of the most intriguing aspects of superluminal speeds is their connection to concepts like wormholes and warp drives. These theoretical constructs suggest ways in which we might navigate the cosmos at speeds greater than light. Wormholes, for example, are hypothetical tunnels through spacetime that could connect distant points in the universe. If they exist, they could potentially allow for superluminal travel without violating the laws of physics as we currently understand them.However, despite these fascinating theories, no experimental evidence supports the existence of superluminal travel. Many scientists remain skeptical, arguing that if such speeds were possible, we would have already observed them in nature. The phenomenon of quantum entanglement, where particles seem to communicate instantaneously over vast distances, has led some researchers to speculate about superluminal effects, but this does not equate to actual travel faster than light.The implications of achieving superluminal speeds extend beyond science fiction. They touch on philosophical questions about the nature of reality and our place in the universe. If we could travel faster than light, what would that mean for our understanding of causality? Would we be able to change the past, or would we simply create alternate timelines? These questions provoke deep discussions among physicists and philosophers alike.In conclusion, the idea of superluminal travel captivates the imagination and challenges our understanding of physics. While current scientific consensus holds that nothing can surpass the speed of light, the exploration of this concept encourages us to think beyond conventional boundaries. As we continue to unravel the mysteries of the universe, who knows what discoveries await us? Perhaps one day, the dream of superluminal travel will transform from a theoretical concept into a tangible reality, reshaping our understanding of time, space, and existence itself.

在物理学的领域中，速度的概念通常与我们日常的经历相关。我们可以轻松地联想到汽车或飞机的速度。然而，当我们深入宇宙的奥秘时，我们遇到了一个挑战我们对速度理解的术语：超光速。这个术语指的是超过真空中光速的速度，大约是299,792公里每秒。要掌握超光速旅行的含义，我们必须首先理解光速在时空结构中的重要性。阿尔伯特·爱因斯坦提出的相对论理论确立了没有什么能超过光速。这一原则对我们理解宇宙有着深远的影响。例如，如果某物能够达到超光速，那么理论上它将允许时间旅行或在浩瀚的距离间进行瞬时通信。想象一下，向另一银河系的朋友发送信息，并在你喝完咖啡之前就收到回复！这样的可能性令人心驰神往，但也带来了物理学上的悖论和挑战。超光速速度最引人入胜的方面之一是它与虫洞和曲速驱动等概念的联系。这些理论构想建议了我们可能以超过光速的速度在宇宙中导航的方法。例如，虫洞是通过时空的假设隧道，可以连接宇宙中遥远的点。如果它们存在，它们可能允许超光速旅行，而不违反我们当前理解的物理法则。然而，尽管这些迷人的理论，没有实验证据支持超光速旅行的存在。许多科学家对此持怀疑态度，认为如果这样的速度是可能的，我们早就该在自然中观察到它们。量子纠缠现象，即粒子似乎在遥远的距离上瞬时通信，导致一些研究人员推测超光速效应，但这并不等同于实际的光速以上旅行。实现超光速速度的意义超越了科幻小说。它们触及关于现实本质和我们在宇宙中位置的哲学问题。如果我们能够超过光速旅行，这对我们理解因果关系意味着什么？我们能改变过去，还是仅仅会创造出替代的时间线？这些问题在物理学家和哲学家之间引发了深入的讨论。总之，超光速旅行的概念吸引着人们的想象力，挑战着我们对物理学的理解。虽然目前科学共识认为没有什么可以超过光速，但对这一概念的探索鼓励我们超越传统界限。随着我们继续揭开宇宙的奥秘，谁知道还有什么发现等待着我们？也许有一天，超光速旅行的梦想将从理论概念转变为切实的现实，重塑我们对时间、空间和存在本身的理解。