Kinetic and structural characteristics of niobium vanadium oxide electrodes for secondary lithium batteries

propylc~e ~r~onale solutlon as positi~ r for rte~argeable filhium batteries. Using t~ dee~mchemical m:asumm~, X-ray dJff~ct ~met~ and X-~y ~ho [o~]~g[rofi spearoscop~ ( E~A ), the ~o~si~e elea~de reaction with dischage and recharge issh~wnas~]~s:Nba\_~V~,(~.0.2-10}+n~++~r ~Li.Nbz ~V~Os, Tbedi~ha~e~a

The kinetic and thermodynamic studies of the intercalation process of lithium ions in the layered structure of niobium disulfide with a 3R-type modification were made. The standard free energy of lithium intercalation into the van der Waals gaps, AG!, was -218 kJ mol-' at 298 K in the range of x = O

Electrochemical behaviors of niobium sulfides suchas 3R-Nb, + . 52 (x 0.25), 2H-NbS2 and NbS, for lithium batteries are investigated in I M LiC1O 4 -propylene carbonate solution . The cathodic reaction in the charge-discharge cycle of the disulfides is shown as follows : NbS 2 +xLi t +xe -= Li~NbS2

The discharge behaviour of T-Nb20, in various electrolytes is unaffected by the choice of solvent, but is strongly dependent on the crystal radius of the solute cation species. Thermodynamic and structural studies show that this is due to the insertion of unsolvated Li+ ions into the crystal lattice