原子氢

原子氢，单个质子，单电子。

OK , atomic hydrogen , one proton , one electron .

原子氢辅助分子束外延生长台阶状表面形貌的研究

Step-Like Morphology Surfaces Formed by Atomic Hydrogen Assisted Molecular Beam Epitaxy

什么是能量的改变，从两个原子氢到H2分子？

What is the energy change going from two atomic hydrogens to one H2 ?

说清楚，这是原子氢的1s原子轨道。

This is the1s . And , just to be clear , this is the1s atomic orbital in atomic hydrogen .

而且射频功率、沉积气压等沉积参数的变化对DLC薄膜沉积过程的中性基团、离子基团以及原子氢等成分都有着明显影响，从而最终影响薄膜沉积过程及薄膜性质。

Both RF power and pressure have distinct influence on radical 's species and proportion in the DLC films deposition process , and the film 's quality is affected finally .

原子氢传感器电池体系静态数学模型

Static mathematical model of cell system for atomic hydrogen sensor

我们讨论的原子氢。

H We 've been talking about atomic hydrogen , H.

原子氢与金刚石表面的相互作用

Studies on the interaction of hydrogen atoms with diamond surface

镍参比电极原子氢电化学传感器

Electrochemical sensor for atomic hydrogen by using nickel reference electrode

但是，它不能仅仅是原子氢。

But , it could be not just atomic hydrogen .

原子氢渗透速率检测电化学传感器的研究

Development of a New Type Electrochemical Sensor for Measuring Hydrogen Atom Permeation Rate

完成了两个电子，它们分别来自于两个原子氢。

I started with two electrons , one each from two atomic hydrogens .

原子氢钝化硅中与铜有关的缺陷

Atomic Hydrogen Passivation of Copper-Related Defects in Silicon

原子氢、氘钝化以及质子注入掺杂硅的红外吸收

Infrared absorption of doped silicon passivated by atomic hydrogen , deuterium and implanted by proton

加氢反应器器壁中可移动原子氢浓度探测电化学氢探头

Electrochemical hydrogen probe for detecting concentration of mobile atomic hydrogen in the wall of hydrogenation reactor

金属设备中原子氢浓度的原位无损检测技术的研究

Study on in-situ nondestructive detection of concentration of atomic hydrogen in the wall of metallic equipment

而原子氢和氢致马氏体在氢致滞后断裂中所起的作用则极小。

The role of atomic hydrogen and hydrogen-induced martensite in hydrogen-induced delayed fracture was very small .

原子氢脉泽

The Atomic Hydrogen Maser

这显然是原子氢，被钢吸收或溶解于钢，会影响其挠性和韧性。

It is apparently atomic hydrogen , absorbed or dissolved in steel , that affects it flexibility and ductility .

我们看过原子氢的薛定谔方程，但其实我们能把他用在更复杂的体系。

We saw the Schr ? dinger equation for atomic hydrogen , but you can write it for more complex systems .

设计并研制了一种外置式的电化学原子氢渗透速率传感器。

An outward attaching electrochemical hydrogen permeation rate sensor was designed and developed , It acted as the signal part of the probe .

通过提高氢气稀释度，利用原子氢在成膜过程中起的刻蚀作用，可以稳定结晶相并去除杂相；

By increasing the H2 dilution ratio , it is found that atomic hydrogen can selectively etch amorphous phase and stabilize crystalline phase .

结果表明，甲基是金刚石生长主要的前驱基团，乙炔导致非金刚石碳沉积，原子氢刻蚀非金刚石碳。

It is shown methyl is the dominant diamond growth precursor , acetylene contributes to non-diamond carbon deposition and atomic hydrogen etches non-diamond carbon .

当重原子氢和等离子体重合时，被释放出的中子会撞击反应堆外壁，并将其加热。

When the atoms of heavy hydrogen fuse in that plasma , neutrons are released that then hit the reactor wall , heating it .

在第四章中，我们对原子氢在Be（10（？）0）薄膜表面的吸附性质做了详细的第一原理计算研究。

In Chapter 4 , we present a first-principles study of the atomic hydrogen adsorption onto the Be ( l01 | - 0 ) thin film .

一些关于氢的东西：，氢气，就像其他元素一样，有同位素，人们在1766年就发现了这一点，卡文迪许分离出原子氢，并且阐述了它的一些性质。

A couple of other things about hydrogen : hydrogen also , like other elements , has isotopes and we already saw that in1766 , Cavendish isolated atomic hydrogen and enunciated some of its properties .

利用热力学方法，讨论了温度、隔膜材料对原子氢传感器电池体系电动势、内电阻的影响，构建了传感器电池体系静态数学模型。

The relationship , that temperature and diaphragm material with electromotive force and internal resistance of cell system of atomic hydrogen sensor , was studied by the thermodynamic means , then a static mathematical model of sensor cell system was formulated .

就所有CVD金刚石沉积方法而言，原子态氢的形成发生在沉积区域附近一选择区域内。

In the case of all CVD diamond deposition methods the formation of atomic hydrogen occurs in a selected volume near the deposition area .

也就是说，稳定金刚石生长用的sp3碳比稳定sp2碳浸蚀用的sp3碳所需的原子态氢要多。

In other words , higher amounts of atomic hydrogen are necessary to stabilize the sp3 carbon for growing diamond than for etching sp2 carbon .

该平行催化氢波被用于测定碘酸根离子氧化原子态氢的表现反应速率常数及提高PAP的分析灵敏度。

The parallel catalytic hydrogen wave was used to obtain the apparent rate constant of the oxidation reaction of atomic hydrogen by iodate ion . Further more , it can improve the analytic sensitivity of PAP .