Cathode material for lithium-ion rechargeable batteries

The invention claimed is: 1. A lithium metal oxide powder for use as a cathode material in a rechargeable battery, consisting of a core and a surface layer, the lithium metal oxide having the general formula Li x (Co a M b A c ) 2−x O 2±δ , with x≦0.995, b>0, c≧0, a+b+c=1, |δ|≦0.1, M=(Mn m Ni n ) with m+n=1, A is a dopant, wherein the core and surface layer are either: a pristine Li cobaltite core and a surface layer comprising a lithium metal oxide compound wherein at least 98 mol % of the metal consists of the elements Li, Mn, Ni and Co; or a doped Li cobaltite core, wherein the dopant A is either one or more of Mg, Ti, Al and Zr, and a surface layer comprising a lithium metal oxide compound wherein at least 98 mol % of the metal consists of the elements Li, Mn, Ni, Co and dopant A, and wherein in both alternatives the surface layer comprises: a phase with rhombohedral symmetry with space group R-3m, and either one or both of a cubic phase oxide having a crystal structure with a Fm-3m space group, and a cubic phase oxide having a crystal structure with a Fd-3mS space group, and wherein the surface layer comprises Mn and Ni enriched islands, the islands having a Mn and Ni concentration that is higher than in the bulk of the particles. 2. The lithium metal oxide powder of claim 1 , wherein x≧0.970. 3. The lithium metal oxide powder of claim 1 , wherein 0.974≦x≦0.993. 4. The lithium metal oxide powder of claim 1 , wherein 0<c≦0.03, and A is either one or more dopants selected from the group consisting of Mg, Ti, Al and Zr. 5. The lithium metal oxide powder of claim 1 , wherein the cubic phase oxide having a crystal structure with a Fm-3m space group has a lattice constant “a” with 4.05<=a<=4.30, and the cubic phase oxide having a crystal structure with a Fd-3mS space group has a lattice constant “a” with 8.055<=a<=8.150, “a” being expressed in Å. 6. The lithium metal oxide powder of claim 1 , wherein the cubic phase oxide having a crystal structure with a Fm-3m space group has a lattice constant “a” with 4.13<=a<=4.20, and the cubic phase oxide having a crystal structure with a Fd-3mS space group has a lattice constant “a” with 8.055<=a<=8.110, “a” being expressed in Å. 7. The lithium metal oxide powder of claim 1 , wherein the amount of cubic phase oxide in the powder is between 0.1 and 3 wt %. 8. The lithium metal oxide powder of claim 1 , wherein the powder has an electrical conductivity of less than 10 −5 S/cm when pressed with 63.7 MPa at 25° C. 9. The lithium metal oxide powder of claim 1 , wherein the powder has an electrical conductivity of less than 10 −8 S/cm, when pressed with 63.7 MPa at 25° C. 10. The lithium metal oxide powder of claim 1 , wherein the surface layer comprises more Mn than the core, and wherein the surface layer comprises less Co than the core. 11. The lithium metal oxide powder of claim 1 , wherein the islands comprise at least 5 mol % of Mn. 12. The lithium metal oxide powder of claim 1 , wherein n≧m, and wherein at the surface of the powder the molar ratio Ni:Mn>1, and said surface Ni:Mn molar ratio being greater than n/m. 13. An electrochemical cell comprising a cathode comprising as active material the lithium metal oxide powder according to claim 1 . 14. A method for preparing a lithium metal oxide powder according to claim 1 , comprising the steps of: providing a mixture of a doped or undoped LiCoO 2 powder, a Ni—Mn—Co comprising powder, and a Li-comprising compound, the mixture comprising more than 90 wt % of the doped or undoped LiCoO 2 powder, and sintering the mixture at a temperature T of at least 910° C., for a time t between 1 and 48 hours, wherein the quantity of the Li-comprising compound in the mixture is selected to obtain a Li over metal ratio in the lithium metal oxide powder with Li:M≦0.99. 15. The method according to claim 14 , wherein the mixture further comprises a compound comprising the dopant A, or wherein the Ni—Mn—Co comprising powder further comprises the dopant A. 16. The method according to claim 14 , wherein the quantity of the Li-comprising compound in the mixture is selected to obtain a Li over metal ratio in the lithium metal oxide powder with 0.95≦Li:M≦0.99. 17. The method according to claim 14 , wherein the Ni—Mn—Co comprising powder is either a Ni—Mn—Co hydroxide, a Ni—Mn—Co oxyhydroxide or a mixture of both. 18. The method according to claim 14 , wherein the doped LiCoO 2 powder comprises either one or more of Al, Mg and Ti and is prepared by sintering a mixture of Li 2 CO 3 and either Co(OH) 2 or Co 3 O 4 , the Co(OH) 2 or Co 3 O 4 being doped with either one or more of Al, Mg and Ti.