... X-ray photoelectron spectrometer X射线光电子能谱 binding energies结合能 Fe catalyst铁催化剂 ...
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一般型碳材(Pure Carbon Materials)与氢气之间的束缚能(Binding Energies) , , 大约为 4~15kJ╱mol 相较之下 活性碳(ActivatedCarbon)与石墨(Graphite)的束缚能较小。
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C1s binding energies C1s电子结合能
N1s binding energies N1s电子结合能
atoms binding energies 原子结合能
exciton binding energies 激子结合能
n s binding energies n1s电子结合能
c s binding energies c1s电子结合能
ground state binding energies 基态结合能
n 1 s binding energies ns电子结合能
c 1 s binding energies cs电子结合能
The analysis of various interactions and pair correlation functions g(r) of all systems indicated that binding energies are mainly provided by Coulomb interaction,also contain the ionic bond.
对体系各种相互作用以及对关联函数g(r)的分析表明,结合能主要由库仑相互作用能提供,还含有部分离子键。
参考来源 - 聚环氧琥珀酸及丙烯酸共聚物阻垢机理的分子动力学模拟·2,447,543篇论文数据,部分数据来源于NoteExpress
Nuclear binding energies are strikingly high.
原子核的结合能是极大的。
So we have this infinite number of possible binding energies.
我们有无穷多的可能的结合能。
The binding energies for the products and the reactants aren't in general going to be equal.
生成物和反应物的束缚能,通常不会相等。
You'll also know that all of these binding energies here are negative, so the negative sign indicates that it's low.
你们将会知道所有的这些,结合能都是负的。
Then we'll move on to talking about the binding energies, and we'll specifically talk about how that differs from the binding energies we saw of hydrogen atoms.
然后我们将会讨论结合能,而且我们将特别地讨论,那个如何与氢原子,的结合能不同,我们讨论氢原子特别深入。
And, subsequently, we looked at photoelectron spectroscopy which is a technique that allows us to determine binding energies, ionization energies being just one example.
随后,我们看了光电子谱,这是一种只用一个样品,能够测量结合能,离子化能的技术。
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