Ionic conductivity (solid state)

Ionic conduction (denoted by λ-lambda) is the movement of an ion from one site to another through defects in the crystal lattice of a solid or aqueous solution.

Ionic conduction is one mechanism of current.^[1] In solids, ions typically occupy fixed positions in the crystal lattice and do not move. However, ionic conduction can occur, especially as the temperature increases.^[2]

Ionic conduction is one of the mechanisms by which microwave ovens are believed to work. Microwaves cause ions dissolved in the microwaved sample to oscillate, colliding with neighboring molecules or atoms. These collisions cause agitation, motion or heat. This mechanism is important when considering the heating behavior of ionic liquids within a microwave.^[3]

Ionic conduction in solids has been a subject of interest since the beginning of the 19th century. Michael Faraday established in 1839 that the laws of electrolysis are also obeyed in ionic solids like lead(II) fluoride (PbF₂) and silver sulfide (Ag₂S).

Silver iodide

Lua error in package.lua at line 80: module 'strict' not found. Lua error in package.lua at line 80: module 'strict' not found. In 1921, Tubandt et al. found that solid silver iodide (AgI) had extraordinary high ionic conductivity. At temperatures above 147 °C, AgI changes into a phase that has an ionic conductivity of ~ 1 –1 cm⁻¹, similar to that of its liquid phase. This high temperature phase of AgI was the first superionic conductor ever discovered. The highly conductive phase of AgI is now known as alpha-AgI. It was shown that a sublattice cationic disorder takes place in alpha-AgI. The liquid-like state of Ag⁺ ions, as proposed by Strock (1934, 1936) and later reinforced by others (Geller, 1977; Funke, 1976), consists of a cubic unit cell of iodide ions (I⁻), in which a total of 42 sites (6 octahedral, 12 tetragonal and 24 trigonal bipyramidal) are available for 2 Ag⁺ ions, as shown in the Figure 1. O' Keeffe and Hyde (1976) have argued that this phase transition in AgI is dramatic and powerful, nothing less than the melting and have also shown that the entropy change at the super-ionic transition is comparable to its value at the melting. Thus, in the -phase, I⁻ ions form a body-centered cubic lattice and the Ag⁺ ions are distributed in such a way that 42 crystallographic equivalent interstices are available for the two Ag⁺ ions.

Alpha phase crystals of various materials like Ag₂S, Ag₂Se, Ag₂Te, etc. were soon discovered (Tubandt, 1932). By the early 1930s, it was demonstrated that these fast ionically conducting solids could be treated entirely the same as aqueous electrolytes from the viewpoint of chemical reactions and thermodynamics, hence these materials were labeled solid electrolytes.

See also

• Lattice energy
• Fast ion conductor

References

1. ↑ Richard Turton. (2000).The Physics of Solids. New York:: Oxford University Press. ISBN 0-19-850352-0.
2. ↑ http://www.teknik.uu.se/ftf/education/Disordered_materials/Ion_conduction.pdf
3. ↑ Kappe, C. O.; Stadler, A. Microwaves in Organic Synthesis and Medicinal Chemistry; Wiley-VCH: Mannheim, 2005. p. 12. ISBN 3-527-31210-2.

External links

• J Chem Phys