In general relativity theory, graviton is the massless tensor particle, which results in gravitation action in proportion to the energy.
在爱因斯坦引力理论下,引力子为零质量的张量粒子,它导致了粒子之间存在着正比于能量的引力作用。
These waves were first predicted by Einstein's general theory of relativity in 1916.
人们最早是在1916年根据爱因斯坦创立的广义相对论预测出引力波的。
In his general theory of relativity, published in 1916, Einstein showed that gravity too can slow time.
在他1916年发表的广义相对论中,爱因斯坦证明了重力可以减慢时间。
His general theory of relativity has proved accurate in predicting how light travels from some of the most distant galaxy clusters in the universe, according to new measurements.
他的广义相对论被证实是正确的,在一项新的测试中,它精确地预测了在宇宙里一些最为遥远星系团那里光的运行。
The effect is tiny but crucial, they added – and was predicted almost 100 years ago by Albert Einstein in his great theory of gravity, general relativity.
这影响虽然细微但非常关键,他们补充道 - 100年前,爱因斯坦在他伟大的重力理论-广义相对论中已经有了这样的预测。
Einstein would tackle this later in his general theory of relativity.
爱因斯坦在他后来的广义相对论中去处理这个问题。
In his theory of general relativity, Einstein realized that space and time can stretch and warp in ways that change the trajectory of light.
爱因斯坦在他的广义相对论中认识到,可以以改变光轨迹的方式对时间和空间进行拉伸和弯曲。
According to the theory of general relativity, the speed and angular momentum of such a large spinning body twists the space and time around it in a process called frame-dragging.
根据爱因斯坦的广义相对论,像银河系这样的巨大自旋物体的速率和角动量在一个称为框架牵引的过程中会扭曲周围的时空。
This week scientists met to discuss plans for a more sensitive detector that could be built in space.Gravitational waves were predicted by Einstein's general theory of relativity in 1916.
这一周来,科学家们举行会晤,讨论一个在太空空间中建造一个更加敏感的探测器的计划。重力场波动是由爱因斯坦在1916年广义相对论中的预测出来。
In his general theory of relativity, Einstein proposed that space and time are distorted by the presence of massive objects.
在整个相对论体系中,爱因斯坦都认为时空是受大质量物体的影响的。
ONE of the most elusive goals in modern physics has turned out to be the creation of a grand unified theory combining general relativity and quantum mechanics, the two pillars of 20th-century physics.
现代物理学中最大的难题之一便是创立一个能够包容广义相对论和量子力学,20世纪物理学两大支柱的终极理论。
These strings produce all known forces and particles in the universe, thus reconciling Einstein s theory of general relativity (the large) with quantum mechanics (the small).
这些“弦”制造了所有已知作用力和宇宙中的粒子,从而达到与爱因斯坦相对论(宏观)与量子力学(微观)理论的协调。
In fact, the premise of Einstein's theory of general relativity was proved within three years of its publication in 1916.
事实上,爱因斯坦广义相对论的假设在1916年发表后3年内就得到了证明。
Two pages of the original manuscript of Albert Einstein's General Theory of Relativity were put on display Thursday afternoon in the Israel Pavilion of the 2010 World Expo in Shanghai.
6日下午,两张爱因斯坦亲手书写的相对论文稿在上海世博会以色列馆展出。
Gravitational waves were predicted by Einstein's general theory of relativity in 1916.
重力场波动是由爱因斯坦在1916年广义相对论中的预测出来。
Let's look back into the two important theory in modern science: general theory of relativity of Einstein and quantum mechanic of Heisenberg.
让我们再看看现代科学的两大理论:爱因斯坦的广义相对论和海森堡的量子力学。
Some major puzzles in black hole theory and General Relativity, including Hawking radiation, information puzzle, singularity theorem and synchronization of clock rate, are presented.
介绍了黑洞理论和广义相对论中的几个重要疑难,涉及霍金辐射、信息佯谬、奇性定理和钟速同步,并给出了可能的解答。
The curvature - or warping - of space was originally proposed by Einstein as early as 1915 in his theory of General Relativity.
曲率-或翘曲-空间最初是由爱因斯坦早在1 9 15年在他的理论的广义相对论。
In 1973, he applied Einstein's general theory of relativity to the principles of 4 quantum mechanics.
1973年,他把爱因斯坦的广义相对论应用于量子力学原理。
More specifically, the problem is the way that time is tied up with space in Einstein's theory of gravity: general relativity.
具体说来,问题出在爱因斯坦的引力理论——在他的广义相对论中,时间和空间是浑然一体的。
Yet they are such a linchpin of general relativity that the theory would crumble like a house of CARDS in a hurricane if they did not exist.
但是这是广义相对论的关键,如果它不存在的话,广义相对论将像暴风中的纸房子一样崩溃。
Maxwell's theory of electromagnetism and Einstein's theory of general relativity are also expressed in the language of differential calculus.
麦克斯韦电磁理论和爱因斯坦的广义相对论也表示的语言微分。
This paper derives in detail the gravitational field of the sun by using the Schwarzschild metric, and expounds the advance of the Mercury's perihelion with the general theory of relativity.
用史瓦西度规详尽地推导了太阳引力场,用广义相对论解释了水星近日点的进动。
This paper derives in detail the gravitational field of the sun by using the Schwarzschild metric, and expounds the advance of the Mercury's perihelion with the general theory of relativity.
用史瓦西度规详尽地推导了太阳引力场,用广义相对论解释了水星近日点的进动。
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