Abstract
In this study, comprehensive survey of formation of disperse forms by the electrolysis from aqueous electrolytes and molten salt electrolysis has been presented. The shape of electrolitically formed disperse forms primarily depends on the nature of metals, determined by the exchange current density (j0) and overpotential for hydrogen evolution reaction as a parallel reaction to metal electrolysis. The decrease of the j0 value leads to a change of shape of dendrites from the needle-like and the 2D fern-like dendrites (metals characterized by high j0 values) to the 3D pine-like dendrites (metals characterized by medium j0 values). The appearing of a strong hydrogen evolution leads to formation of cauliflower-like and spongy-like forms (metals characterized by medium and low j0 values). The other disperse forms, such as regular and irregular crystals, granules, cobweb-like, filaments, mossy and boulders, usually feature metals characterized by the high j0 values. The globules and the carrot-like forms are a characteristic of metals with the medium j0 values. The very long needles were a product of molten salt electrolysis of magnesium nitrate hexahydrate. Depending on the shape of the disperse forms, i.e. whether they are formed without and with vigorous hydrogen evolution, formation of all disperse forms can be explained by either application of the general theory of disperse deposits formation or the concept of "effective overpotential". With the decrease of j0 value, the preferred orientation of the disperse forms changed from the strong (111) in the needle-like and the fern-like dendrites to randomly oriented crystallites in the 3D pine-like dendrites and the cauliflower-like and the spongy-like forms.
Highlights
In this study, comprehensive survey of formation of disperse forms by the electrolysis from aqueous electrolytes and molten salt electrolysis has been presented
The disperse forms of metal deposits can be obtained by electrolysis from aqueous electrolytes and molten salt electrolysis [1,2]
The main parameters affecting the shape of disperse forms are: the type and composition of electrolytes, temperature of electrolysis, the type of cathode, stirring of electrolyte, the addition of specific substances known as additives, etc
Summary
The disperse (powder, irregular) forms of metal deposits can be obtained by electrolysis from aqueous electrolytes and molten salt electrolysis [1,2]. According to the exchange current density, melting point and overpotential for hydrogen evolution reaction, metals are classified into three classes [3]: a) Class I, so-called normal metals like silver, cadmium, lead, tin and zinc This group of metals is characterized by the high values of both the exchange current density (j0 > 1 A dm-2; j0 is the exchange current density) and overpotential for hydrogen evolution reaction, and low melting point, b) Class II, so-called intermediate metals like copper, gold and silver (ammonium electrolyte). This mini Authors review gives a comprehensive survey of morphological characteristics of disperse forms of lead, silver and zinc (the normal metals), copper and silver (the intermediate metals) and nickel (the inert metal)
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