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Rubidium silver iodide

Summary

Rubidium silver iodide is a ternary inorganic compound with the formula RbAg4I5. Its conductivity involves the movement of silver ions within the crystal lattice. It was discovered while searching for chemicals which had the ionic conductivity properties of alpha-phase silver iodide at temperatures below 146 °C for AgI.[1]

RbAg4I5 can be formed by melting together[2] or grinding together[3] stoichiometric quantities of rubidium iodide and silver(I) iodide. The reported conductivity is 25 siemens per metre (that is a 1×1×10 mm bar would have a resistance of 400 ohms along the long axis).

The crystal structure is composed of sets of iodine tetrahedra; they share faces through which the silver ions diffuse.[4]

RbAg4I5 was proposed around 1970 as a solid electrolyte for batteries, and has been used in conjunction with electrodes of silver and of RbI3.[1] Its conductivity does not exhibit substantial variation with changes in relative humidity.[5]

Rubidium silver iodide family is a group of compounds and solid solutions that are isostructural with the RbAg4I5 alpha modification. Examples of such advanced superionic conductors with mobile Ag+ and Cu+ cations include KAg4I5, NH4Ag4I5, K1−xCsxAg4I5, Rb1−xCsxAg4I5, CsAg4Br1−xI2+x, CsAg4ClBr2I2, CsAg4Cl3I2, RbCu4Cl3I2 and KCu4I5.[6][7][8][9]

References edit

  1. ^ a b Smart, Lesley & Elaine A. Moore (2005). Solid State Chemistry: An Introduction. CRC Press. p. 192. ISBN 0-7487-7516-1.
  2. ^ Popov, A. S.; Kostandinov, I. Z.; Mateev, M. D.; Alexandrov, A. P.; Regel, Liia L.; Kostandinov; Mateev; Alexandrov; Regel (1990). "Phase analysis of RbAg4I5 crystals grown in microgravity". Microgravity Science and Technology. 3: 41–43. Bibcode:1990MicST...3...41P.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  3. ^ Peng H.; Machida N. Shigematsu T. (2002). "Mechano-chemical Synthesis of RbAg4I5 and KAg4I5 Crystals and Their Silver Ion Conducting Properties". Journal of the Japan Society of Powder and Powder Metallurgy. 49 (2): 69–74. doi:10.2497/jjspm.49.69.
  4. ^ Geller, S. (1967). "Crystal Structure of the Solid Electrolyte, RbAg4I5". Science. 157 (3786): 310–312. Bibcode:1967Sci...157..310G. doi:10.1126/science.157.3786.310. PMID 17734228. S2CID 44294829.
  5. ^ Akin, Mert; Wang, Yuchen; Qiao, Xiaoyao; Yan, Zhiwei; Zhou, Xiangyang (20 September 2020). "Effect of relative humidity on the reaction kinetics in rubidium silver iodide based all-solid-state battery". Electrochimica Acta. 355: 136779. doi:10.1016/j.electacta.2020.136779. S2CID 225553692.
  6. ^ Geller S.; Akridge J.R.; Wilber S.A. (1979). "Crystal structure and conductivity of the solid electrolyte α-RbCu4Cl3I2". Phys. Rev. B. 19 (10): 5396–5402. Bibcode:1979PhRvB..19.5396G. doi:10.1103/PhysRevB.19.5396.
  7. ^ Hull S. Keen D.A.; Sivia D.S.; Berastegui P. (2002). "Crystal Structures and Ionic Conductivities of Ternary Derivatives of the Silver and Copper Monohalides – I. Superionic Phases of Stoichiometry MAg4I5: RbAg4I5, KAg4I5, and KCu4I5". Journal of Solid State Chemistry. 165 (2): 363–371. Bibcode:2002JSSCh.165..363H. doi:10.1006/jssc.2002.9552.
  8. ^ Despotuli A.L.; Zagorodnev V.N.; Lichkova N.V.; Minenkova N.A. (1989). "New high conductive CsAg4Br1−xI2+x (0.25 < x < 1) solid electrolytes". Sov. Phys. Solid State. 31: 242–244.
  9. ^ Lichkova N.V.; Despotuli A.L.; Zagorodnev V.N.; Minenkova N.A.; Shahlevich K.V. (1989). "Ionic conductivity of solid electrolytes in the two- and three-components AgX–CsX (X = Cl, Br, I) glass-forming systems". Sov. Electrochem. 25: 1636–1640.

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