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Beilstein J. Nanotechnol. 2015, 6, 1821–1839, doi:10.3762/bjnano.6.186
Figure 1: Gravimetric and theoretical volumetric capacities of metals and complex hydrides compared with thos...
Figure 2: Theoretical equilibrium potential for the MHx/Li cell vs Li+/Li0. a) For binary hydrides M = Y, La,...
Figure 3: Potentials vs Li+/Li0 of MHx/Li cells (V) as a function of the mole fraction of Li (x) recorded bet...
Figure 4: Potential profile and XRD patterns of MgH2 electrode at different stages of the conversion reaction...
Figure 5: Potential profile and XRD patterns of MgH2 electrode at various stages of the conversion reaction. ...
Figure 6: Potential profile of a MgH2 electrode at various stages of the conversion reaction. a) Evolution of...
Figure 7: Summary of the dehydrogenation process of TiH2 electrode δ-TiH2−x (fcc): black triangles, TiH (fco)...
Figure 8: Discharge curves for a) Mg2FeH6, b) Mg2CoH5 and c) Mg2NiH4 electrodes prepared by reactive grinding...
Figure 9: In situ XRD patterns of a) Mg2FeH6, b) Mg2CoH5 and c) Mg2NiH4 and d) Mg2FeH6-10% Ct,z electrodes pr...
Figure 10: The evolution of the potential (V) as a function of x (mole fraction of Li) for a MgH2 electrode pr...
Figure 11: a) DSC traces of commercial MgH2 unground and ground for 20 h. b) Evolution of the potential (V) as...
Figure 12: a) Evolution of the potential (V) as a function of x (mole fraction of Li) for a MgH2 electrode pre...
Figure 13: a) Absorption and b) desorption kinetics at 350 °C for Mg–10%C10,320 composite (open squares): firs...
Figure 14: Evolution of the potential (V) as a function of x (mole fraction of Li) for MgH2 electrodes cycled ...
Figure 15: Graphite BET surface area (m2·g−1) and d(002) interlayer distance (Å) as a function of grinding tim...
Figure 16: Thermodesorption of commercial MgH2 (black diamonds) and commercial MgH2 ground 4 h with 10% of Ct,z...
Figure 17: Evolution of the potential (V) as a function of x (mole fraction of Li) for MgH2 electrodes cycled ...
Figure 18: Evolution of the potential (V) as a function of x for a Li/MgH2 cell that was cycled down to 0.15 V...
Figure 19: Capacities of a MgH2 electrode obtained after three absorptions of hydrogen and then ground for 4 h...
Figure 20: Evolution of the potential (V) as a function of x (mole fraction of Li) for MgH2 electrodes cycled ...
Figure 21: Electrochemical cycling performance for MgH2 composite electrodes: MgH2–18% Ct,z (black triangles),...
Figure 22: Potential profile of a) TiH2 electrode ground for 5 h with 10% of Ct,z carbon b) Ti + 2LiH electrod...