relativistic

简明释义

英[ˌrelətɪˈvɪstɪk]美[ˌrelətɪˈvɪstɪk]

adj. 相对的；相对论的

英英释义

单词用法

同义词

反义词

例句

1.Relativistic electrons produce light that goes to the optical resonator with absolute vacuum inside.

相对论电子所产生的光线将进入完全真空的光学谐振器当中。

2.The antimatter particle was created at the Relativistic Heavy ion Collider at Brookhaven National Laboratory in Upton, n.y..

纽约州阿普顿布鲁克海文国家实验室的相对重离子对撞机所创建的反物质粒子。

3.So, how does this relativistic transparency happen inside plasma?

那么，等离子体中的相对论透明是怎样发生的呢？

4.In any relativistic theory this difficulty occurs, even in the old classical theory of Lorentz.

在任何相对性理论中(负能态)这个困难都存在着，它甚至早在洛伦兹的旧经典理论中就已经存在。

5.Another amazing feat of physics came out of Brookhaven's Relativistic Heavy Ion Collider this year.

一个惊人的物理学壮举来自今年的布鲁克海文实验室的相对重离子对撞机。

6.Even more dramatically, relativistic chips could employ logic that is more sophisticated than the binary operations all computers now use.

更引人注目的是，相对论性晶片可运用比目前所有电脑用的二进位运算更复杂的逻辑。

7.The calculation shows that electrons distributed on a large scale can be accelerated to relativistic energy in vacuum.

计算表明分布在一个相当大范围的电子可以在真空中被加速到相对论能量。

8.One incorporated their newly hypothesised relativistic effects while the other did not.

其中一个模型结合使用了相对论效应的新假设，另一个没有用。

9.But some relativistic calculations suggested it might actually behave like a different element, the inert (and non-metallic) gas, radon.

但基于相对论进行的计算表明，它更像一种独特元素、惰性(非金属)气体氡。

10.Einstein's theory introduced the concept of relativistic mass, which increases with velocity.

爱因斯坦的理论引入了相对论的质量概念，该质量随着速度增加而增加。

11.In a relativistic framework, time can appear to slow down for objects moving at high speeds.

在一个相对论的框架中，时间对于以高速运动的物体来说可能会显得减缓。

12.GPS satellites must account for relativistic effects to provide accurate positioning.

GPS卫星必须考虑相对论的效应才能提供准确的位置服务。

13.The equations of relativistic physics are essential for understanding phenomena in high-energy particle collisions.

理解高能粒子碰撞现象需要使用相对论的物理方程。

14.Astrophysicists study relativistic jets emitted by black holes.

天体物理学家研究黑洞发出的相对论的喷流。

作文

In the realm of physics, the term relativistic refers to the effects that become significant when objects move at speeds comparable to the speed of light. This concept was fundamentally introduced by Albert Einstein in his theory of relativity, which revolutionized our understanding of space, time, and gravity. To grasp the implications of relativistic physics, one must first understand the principles that govern motion at high velocities.When we talk about relativistic effects, we often refer to phenomena such as time dilation and length contraction. Time dilation suggests that time moves slower for an object in motion compared to a stationary observer. For instance, if a spaceship travels at a significant fraction of the speed of light, the astronauts aboard would age more slowly relative to people on Earth. This fascinating aspect of relativistic physics challenges our intuitive perceptions of time as a constant, universal measure.Length contraction, another relativistic effect, states that an object in motion will appear shorter along the direction of its velocity compared to when it is at rest. This means that if a train were to travel at near-light speed, its length would contract from the perspective of a stationary observer. These concepts not only have theoretical implications but also practical applications in modern technology, such as GPS satellites, which must account for relativistic effects to provide accurate positioning data.The significance of relativistic physics extends beyond mere academic curiosity; it has profound implications for our understanding of the universe. For example, black holes and neutron stars exhibit extreme gravitational fields where relativistic effects dominate. The behavior of matter and energy in such environments can only be described using the principles of relativity.Moreover, the study of relativistic particles has opened new frontiers in particle physics. High-energy collisions in particle accelerators produce particles moving at speeds close to that of light, allowing scientists to observe relativistic effects firsthand. These experiments help us probe the fundamental forces of nature and the building blocks of matter.In summary, the term relativistic encapsulates a range of phenomena that arise when dealing with high-speed motion and strong gravitational fields. Understanding these effects is crucial not only for physicists but also for anyone interested in the workings of the universe. The implications of relativistic physics challenge our everyday experiences and push the boundaries of what we know about time, space, and the fundamental nature of reality. As we continue to explore the cosmos and delve deeper into the mysteries of the universe, the principles of relativistic physics will remain at the forefront of scientific inquiry, guiding our quest for knowledge and understanding.

在物理学领域，术语相对论的指的是当物体以接近光速的速度运动时变得显著的效应。这个概念最初由阿尔伯特·爱因斯坦在他的相对论理论中提出，彻底改变了我们对空间、时间和引力的理解。要掌握相对论的物理学的含义，首先必须理解在高速运动下支配运动的原则。当我们谈论相对论的效应时，我们通常指的是诸如时间膨胀和长度收缩等现象。时间膨胀表明，对于一个运动中的物体，相比于静止观察者，时间流动得更慢。例如，如果一艘宇宙飞船以接近光速的速度飞行，船上的宇航员将相对于地球上的人们变得衰老得更慢。这种相对论的物理学的迷人方面挑战了我们对时间作为一个恒定的、普遍的度量的直观感知。长度收缩是另一个相对论的效应，指出运动中的物体在其速度方向上会显得比静止时更短。这意味着如果一列火车以接近光速的速度行驶，从静止观察者的角度来看，它的长度会收缩。这些概念不仅具有理论意义，还有实际应用，例如GPS卫星，它们必须考虑相对论的效应，以提供准确的定位数据。相对论的物理学的重要性超出了单纯的学术好奇心；它对我们理解宇宙有深远的影响。例如，黑洞和中子星表现出极端的引力场，在这些环境中相对论的效应占主导地位。在这样的环境中，物质和能量的行为只能用相对论的原则来描述。此外，相对论的粒子的研究为粒子物理学开辟了新的前沿。在粒子加速器中进行的高能碰撞产生以接近光速移动的粒子，使科学家能够亲身观察相对论的效应。这些实验帮助我们探测自然的基本力量和物质的构建块。总之，术语相对论的概括了一系列在处理高速运动和强引力场时出现的现象。理解这些效应对物理学家以及任何对宇宙运作感兴趣的人来说都是至关重要的。相对论的物理学的含义挑战了我们的日常经验，并推动了我们对时间、空间和现实的基本性质的认识的边界。随着我们继续探索宇宙并深入研究宇宙的奥秘，相对论的物理学原则将始终处于科学探究的前沿，引导我们追求知识和理解的旅程。