电化学势

植物细胞质膜和液泡膜上的H+-ATPase消耗ATP能量建立跨膜质子电化学势梯度，推动各种离子和小分子代谢产物进行跨膜运输。

Plant cell plasma membrane and vacuolar membrane H + - ATPase consumes ATP energy establishment of transmembrane proton electrochemical potential gradient , promoting a variety of ions and small molecule metabolites to transmembrane transport .

关于电化学势问题的讨论本文从物理学的角度探讨了什么是电化学势，并讨论了电化学势在物理化学中的应用。

What is chemical potential from physical point and application of electrical chemical potential in physical chemistry were discussed in this paper .

经含氧基修饰后的金刚石薄膜的性质发生变化，如：电导率变小、电化学势窗更宽。

The property of diamond film after modification has changed , such as the conductance diminishing , wider potential window in aqueous solution .

本文利用两个带电的简单相之间的平衡条件&电化学势相等，导出了电化学成核和长大的基本热力学关系和晶核密度（或成核速度）公式。

In this paper , the thermodynamic relations between electrochemical nucleation and growth arc derived using the general condition of equilibrium between two simple charged phaser , i.

分析了电解液-敏感膜界面的选择性吸附过程，利用电化学理论得到界面势与液体pH值的定量关系，结果与实验一致。

The selective binding process was analysed and the quantitative result was obtained utilizing the theory of electrochemistry , according to experimental results .

体系中成分不同区域的费米能级差导致电子从费米能级高的区域流向费米能级低的区域，正是费米能级差构成了镁合金电化学腐蚀的电动势。

It is just the difference of fermi levels that forms the electrodynamic force of the electrochemical corrosion in magnesium alloys .