Abstract
Li2SO4 as a model ionic conductor has received very much attention over several decades. Especially, in recent years Li2SO4 and Li2SO4-Al2O3 have been mentioned as promising proton conducting electrolytes for applications such as intermediate temperature fuel cells and novel cogeneration systems regarding H2S handling devices. This has encouraged us to strive towards further improvement of the properties of the materials to meet the demands of the applications.
In order to improve the properties of this system, a new process, a suspension technique, has been recently developed to prepare nanostructured powder and thin film Li2SO4-Al2O3 membranes. The powders and thin films have a well crystallised structure composed of two phases, Li2SO4 and γ-Al2O3, and excellent mechanical strength. The thin film thickness is in the scale of a few to several mm with a smooth and shining surface and a homogeneous macroscopic structure.
It is a very interesting phenomenon that all samples show no significant conductivity increase at the temperature of the phase transition (∼ 577 °C) from β to α phase of pure Li2SO4. This transition has important significance for applications. The conductivity of the two-phase film materials has been greatly enhanced, where the xLi2SO4-(1-x)Al2O3 (x=58) sample shows the highest conductivity, about 1 S/cm at 600 °C; the activation energy decreases with increasing Li2SO4 content. These results agree with the so called composite effect for the conductivity enhancement observed earlier for two-phase bulk materials.
Based on the four-step proton conducting mechanism in sulphate-based materials, this work may propose a new mechanism. The protons might jump in a water network associated with the water molecular re-orientation, which is accompanied with the single proton jump of the four-step transportation among SO 2−4 groups from one Li2SO4 molecule to another. The former mechanism occur in the interfacial region between the Li2SO4 and the Al2O3 grains, while the latter occur in the bulk of the Li2SO4 grains. These thin film materials are intended for use as proton conducting ceramic membranes in applications such as desulphurisation and fuel cell co-generation plants.
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6. References
A. Lundén and J. O. Thomas, in: High Conductivity Solid Ionic Conductors (T. Takahashi, ed.) World Sci. Pub., Singapore, 1989, p. 45.
A. Lundén, in: Solid State Ionics: New Developments, (B.V.R. Chowdari, M.A.K.L. Dissanayake and M.A. Careem, eds.) World Scientific, Singapore (1996) p. 23.
N. F. Uvarov, O. P. Shrivastava and E. F. Hairetdinov, Solid State Ionics36, 39 (1989); N. F. Uvarov, V. P. Isupov, V. Sharma and A. K. Shukla, Solid State Ionics51, 41 (1992); N. F. Uvarov and E. F. Hairetdinov, Solid State Phenomena39, 27 (1994).
B. Zhu and B.-E. Mellander, J. Power Sources52, 289 (1994).
B. Zhu, Ionics2, 386 (1996).
B. Zhu, K. Rundgren and B.-E. Mellander, Solid State Ionics (1997) 385.
Peterson and J. Winnick, J. Electrochem. Soc.143, L55 (1996).
B. Zhu and B.-E. Mellander, Solid State Ionics70/71, 125 (1994).
B.-E. Mellander and L. Nilsson, Z. Naturforsch.38a, 1396 (1983).
B. Zhu and B.-E. Mellander, Ferroelectrics167, 1 (1995).
B. Zhu and B.-E. Mellander, Solid State Ionics70/71, 285 (1994).
P. Burtin, J. P. Brunelle, M. Pijolat and M. Soustelle, Appl. Cataly.34, 239 (1987).
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Zhu, B., Xia, CR., Albinsson, I. et al. Structural and electrical properties of γ-alumina - lithium sulphate films. Ionics 4, 330–335 (1998). https://doi.org/10.1007/BF02375874
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DOI: https://doi.org/10.1007/BF02375874