17 research outputs found

    Improving ionic conductivity by Mg-doping of A2SnO3 (A=Li+, Na+)

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    The search for Li ions conducting ceramics is burgeoning, owing to the regain interest for solid state batteries. Here we investigate the effect of Mg substitutions on the ionic conductivity of the A2SnO3 (A=Li, Na) phases. Pure A1.8Mg0.1SnO3 and A2.2Mg0.1Sn0.9O3 were structurally characterized and their ionic conductivity was measured by AC impedance spectroscopy. We show a decrease of the activation energy with increasing the Mg substitution and found ionic conductivities three and two orders of magnitude higher for Li2.2Mg0.1Sn0.9O3 and Na1.8Mg0.1SnO3 as compared to pristine Li2SnO3 and Na2SnO3, respectively. Neutron diffraction was used to determine the Mg localization in the crystal structure and to provide a rationale for the ionic conductivity changes. Our results confirm the high sensitivity of the ionic conductivity on chemical substitutions, even limited ones

    Vers lŽobtention de nouveaux matériaux hiérarchisés par synthÚse topotactiques

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    À l'heure actuelle, il y a un intĂ©rĂȘt croissant pour l’adaptation des propriĂ©tĂ©s physique des solides contenant des mĂ©taux de transition en modifiant leurs rĂ©seaux ioniques. Ces changements topologiques modifient non seulement le degrĂ© d’oxydation du mĂ©tal de transition, mais peuvent Ă©galement modifier sa sphĂšre de coordinence, ainsi que les connectivitĂ©s cation-anion-cation Ă  longue distance, pouvant conduire Ă  des changements radicaux de leurs propriĂ©tĂ©s physiques.Dans ce contexte, mon travail de thĂšse, rĂ©alisĂ© au laboratoire UCCS Ă  Lille (France), a consistĂ© en une Ă©tude approfondie de deux diffĂ©rents exemples de transformations topotactiques. PremiĂšrement, je prĂ©sente lÂŽĂ©change anionique ainsi que l'exfoliation en nano-feuillets chargĂ©s positivement, de l'oxo-bromure de cobalt 14H-Ba7Co6BrO17. Le processus d'exfoliation a Ă©tĂ© caractĂ©risĂ© structuralement Ă  l’aide de techniques telles que les microscopies, la diffraction ou l’absorption des rayons X.Dans la deuxiĂšme partie de mon travail, une Ă©tude complĂšte du processus d’exsolution reversible du fer dans BaFe2(PO4)2 a Ă©tĂ© effectuĂ©e, en Ă©tablissant une relation entre les Ă©volutions structurales et la quantitĂ© de fer exsolutĂ©. Une Ă©tude sur l'insertion Ă©ventuelle du lithium dans la structure de la phase la plus lacunaire en fer, BaFe1.33(PO4)2, ainsi que ses capacitĂ©s en tant que cathode pour batteries au lithium, a Ă©galement Ă©tĂ© rĂ©alisĂ©e. En outre, des Ă©tudes structurales et magnĂ©tiques des solutions solides BaFe2-YMY (PO4)2 par substitution du mĂ©tal par Co2+ ou Ni2+a aussi Ă©tĂ© rĂ©alisĂ©e.Enfin, dans la derniĂšre partie de ce manuscrit, je prĂ©sente trois phases diffĂ©rentes Ă  base de fer qui ont Ă©tĂ© dĂ©couvertes lors de prospection pour trouver de nouvelles phases ayant des capacitĂ©s de transformations topotactique.At present, there is growing interest in tuning the physical behavior of solids containing transition metals by modifying their ionic lattices. These topological changes modify not only the electron count (through reduction or oxidation) but can also modify the local transition metal coordination sphere and the long-range cation-anion-cation connectivity, potentially leading to dramatic changes in their physical behavior. In this context, my PhD work developed in the UCCS laboratory at Lille (France), has consisted in a deep study of two different examples of topotactic transformations. Firstly I have performed anionic exchange as well as exfoliation into positively-charged nanoflakes, on the oxybromide cobaltites 15H-Ba7Co6BrO17. This exfoliation process has been structurally characterized by different techniques as microscopies, X-Rays diffractions and absorptions. For the last two, synchrotron radiation was used, the experiments being performed at SOLEIL.Secondely, a full study of the reversible iron exsolution process in BaFe2(PO4)2 has been carried out, establishing a relation between the structural features and the amount of iron exsoluted. A study about a possible lithium insertion in the lattice of the most exsoluted phase, BaFe1.33(PO4)2, as well as its capabilities determination as cathode in Li batteries was also performed. In addition, structural and magnetic studies has been realized in the substituted solid solutions of BaFe2-yMy(PO4)2 with M2+ = Co2+, Ni2+.Finally, the last part of the manuscript presents three different iron phases discovered during my prospecting work for new phases having abilities for topotactic transformation

    Polymorphism in Li 4 Zn(PO 4 ) 2 and Stabilization of its Structural Disorder to Improve Ionic Conductivity

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    International audienceRealization of the vulnerability of current rechargeable battery systems drives the research of solid electrolytes. In the search for a new Li ion conductor, we explore the rich crystal chemistry of Li 4 Zn(PO 4) 2 which presents a low temperature monoclinic (α-) and a high temperature orthorhombic (ÎČ-) polymorph. We solved the crystal structure of the ÎČ-phase and found that it has a disordered Li/Zn-sublattice while showing the largest conductivity; however it could not be stabilized at room temperature by quenching. We discovered that the partial substitution of Zn 2+ with Ga 3+ in Li 4-x Zn 1-x Ga x (PO 4) 2 first leads to an intermediate ÎČ' phase. Increasing the Ga content to 0.5 mol pfu. enables to stabilize the pure ÎČ-phase at room temperature, which exhibits a conductivity by several orders of magnitudes higher than the pristine sample. The crystal structures of the new ÎČ'/ÎČ-phases have been solved to elucidate the conduction mechanism, which confirms the high sensitivity of ionic conductivity on disorder
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