The Li-storage and cycling behavior of the mixed-metal carbonate, nano-(Cd(1/)3Co(1/3)Zn(1/3))CO3 (CCZC) prepared under ambient conditions by the precipitation method are reported. A reversible capacity of 680 ( /- 10) mAhg(-1), corresponding to 3.5 moles of cyclable Li per mole of the CCZC (theor., 3.33 moles of Li) stable in the range 8-60 cycles is observed when cycled at 0.09 C in the range, 0.005-3.0 V vs. Li. The nano-CCZC also shows stable and reversible capacities at various C- rates up to 170 cycles. At 0.6 C, the observed capacity of 360 ( /- 10) mAhg(-1) is comparable to the theoretical capacity (372 mAhg(-1)) of the graphite used in the present-day Li- ion batteries. On the basis of galvanostatic cycling, cyclic voltammetry, ex situ-XRD, -TEM and -SAED studies, a reaction mechanism is proposed in which the CCZC is first reduced by Li to nano-metal (M = Cd, Co and Zn) particles embedded in amorphous Li2CO3 and this is followed by the formation of alloys (Li-Zn and Li-Cd). Upon charging the electrode, the de-alloying reaction and metal carbonate (MCO3) formation occurs, thereby contributing to the reversible capacity. We have shown for the first time that the carbonate ion (CO3-) is as good as the oxide, fluoride or oxy-fluoride ion in enabling the reversible 'conversion' and alloying-de-alloying reactions involving both transition and non-transition metal ions.

• 出版日期2009-7-28