它是由“自身电离”这一过程形成的。
人们是如何暴露在电离辐射下的?
它炫目的色彩归功于电离氢。
那么让我们来比较一下它们的电离能。
例如,我能观察锂的电离。
我们可以计算这的电离能。
电离能,我们知道也就是,负的结合能。
The ionization energy, of course, is just the negative of the binding energy.
让我们来看一下电离能最低在中间的情况。
Let's take a look at the lowest ionization energy in the center case.
红色部分来自电离氢。
我们绝不会见到一个,电离能是负值的情况。
We will never have a case where ionization energy is negative.
我们能够计算电离能。
因此,按照电离能,我们应该把硫放在中间。
So, in terms of ionization energy, we would expect to see sulfur in the middle.
人类每天都暴露在电离辐射下。
Human beings are exposed to natural radiation on a daily basis.
我们知道结合能,总是负的,电离能总是正的。
We know that binding energy is always negative, ionization energy is always positive.
免疫系统对电离辐射极度敏感。
The immune system is extremely sensitive to ionizing radiation.
系统是电离辐射的主要危象器官。
Hematopoietic system is a crisis organ of ionization radiation cxposure.
人们通常都暴露在电离辐射下吗?
碱和水发生反应被称为电离反应。
When a base reacts with water we are talking about an ionization reaction.
什么是电离辐射?
本文研究了波在暖电离层中的传播。
The wave propagation in the warm ionosphere is studied in this paper.
它是由“自身电离”生成的。
电离室电极用高原子序数的金属制造。
气体是由光致电离加热的。
医用电离辐射是最大的人工辐射应用领域。
Medical ionizing radiation plays most part in artificial radiation application.
电离辐射是一把双刃剑。
这种添加剂比低电离电位蒸汽添加剂优越。
Therefore this additive is superior to those with low ionisation potential.
这种模式是非常敏感的电离层多普勒调制。
This mode is very sensitive to the ionospheric Doppler modulation.
那么,从电离能的角度考虑,大家会把哪个原子放在中间?
So, thinking about ionization energy, which atom would you put in the middle here?
辐射伤害:曝露在电离辐射中造成的组织损伤。
Radiation injury: Tissue damage caused by exposure to ionizing radiation.
现在再来看一下后来少数几种原子的电离电势值。
Let us now look at the ionization potentials for the next few atoms.
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