The energy of a light photon or particle is different for each color.
可见光子或粒子的能量因颜色不同而不同。
The Planck–Einstein relation describes the energy of each photon in terms of the photon's frequency.
普朗克—爱因斯坦关系式用光子的频率来描述每个光子的能量。
光子发射,可能。
And what is the energy of that photon?
那什么是光子呢?
And it is given off in the form of a photon.
它一个光能的形式释放。
So it does not mean that we have more energy per photon.
它不代表每一个光子,有更高的能量。
So for every photon we have 2.84 times 10 to the -19 joules.
每一个光子有,2,84乘以10的- 19次方焦耳。
When hit by a blue photon, a cryptochromemolecule loses an electron.
当受到蓝色光子撞击后,隐色素分子会失去一个电子。
As a result, the electron will not emit a photon when it loses energy.
结果就是,当电子损失能量是,它不会释放光子。
By recording each photon, she actually destroys what she is measuring.
读取每个光子,实际上也是其破坏光子上信息的过程。
In the first, a photon is polarised either vertically or horizontally.
第一种模式中,光子经过偏振处理,转为垂直方向或水平方向振动。
How can the law accommodate a further output signal, a photon or optical signal?
这定律如何适应进一步输出信号,光子或光信号?
You also have to make the photon or electron sit still, another problem entirely.
你还不得不让光量子或电子保持静止,这又是另一个完全不同的难题。
Once it has passed through the slits, the photon strikes a position sensitive detector.
一旦它通过通过狭缝,光子就会击中位置灵敏探测器。
So, remember what we're talking about here is the amount of energy that's in each photon.
所以,记住我们这里谈论的是,每个光子的能量值。
When processing is complete, the ions can be made to release the "answer" as a photon.
当处理完成,可以使离子以声子的形式释放答案。
This in turn left its mark on the polarization of the next photon, so amplifying the signal.
光子就这样轮流地将它的偏振标记留给下一个光子,因而增强了信号。
The first that we need to know the energy of the photon that's incident on our gaseous atom.
首先,我们需要知道,入射到气体原子的光子的能量。
That's sometimes confusing for people, because it seems like okay, is it a photon or is it an electron.
有时候这对人们来说是令人迷惑的,因为它看起来好像是对的,它是一个光子还是一个电子?
To facilitate the measurements, Professor Gross and his team captured the photon in a special box, a resonator.
为了方便测量,格罗斯教授和他的团队通过一个特殊的盒子——谐振器——来捕获光子。
Although very tiny, each photon carries a small amount of momentum away from the asteroid, giving it a tiny kick.
尽管非常微弱,但每一个光子都携带着微量的动量离开小行星,给小行星形成一种微弱的反冲。
If it s in the first state, and it falls out of the conduction band, it will release its extra energy as a photon.
如果是在第一形态,并且它逃离出了传导带,他会以光子的形式释放多余的能量。
We start at this lower energy state and go up that means we need to absorb a photon, we have to take in energy.
我们从一个低能级开始,到一个高能级去,这意味着需要吸收一个光子,我们要获得能量。
Once entangled, a photon can carry any information stored in the atom's quantum state to other parts of the computer.
一旦发生纠缠,光子可以将储存在原子量子态中的任何信息传递到计算机的其他位置。
Yes. In fact, there is not enough energy in a single photon to go ahead and eject an electron from this zinc surface.
是的,事实上,这里的光子没有足够的能量,去从锌表面逐出一个电子。
In a linear measurement, each photon would interact separately with the atoms, resulting in a relatively weak signal.
在一个线性测量中,每一个光子可以单独地与原子进行相互作用,这样得到的是一个相对较弱的信号。
When a photon strikes the surface, it excites an electron to a higher energy level, which is specific to the material.
当光子照射到材料表面时,电子受到光子的激发由一个能级跳到更高的能级上,而这些能级对材料来说是特定的。
Some of these would boost the size of the photon-pair bump, though making it big enough still seems to be a stretch.
这些玻色子可能推动光子纠缠对爆炸的强度,虽然使爆炸足够大仍然需要时日。
According to this model, when a photon hits the compass, entangled electrons are scattered to different parts of the molecule.
根据这一模型,当一个光子撞击罗盘时,处于纠缠态中的电子分散到分子的不同部位。
Quantum walk experiments using one photon have been done before and can even be modelled exactly by classical wave physics.
此前做过的单光子量子游走试验甚至可以用经典波动理论解释。
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