Aluminum dry-coated and heat treated cathode material precursors

The invention claimed is: 1. A particulate precursor compound for manufacturing an aluminum coated lithium transition metal (M)-oxide powder usable as an active positive electrode material in lithium-ion batteries, each particle of said precursor compound comprising: a transition metal (M)-oxide core; and a non-amorphous aluminum oxide Al 2 O 3 coating layer covering said core, wherein said particulate precursor has an aluminum doping level equal to or greater than 5 mol%, said doping level being equal to: Al/(Al +M), with Al +M =1, wherein said particulate precursor compound has a general formula (M-oxide) a .(Al 2 O 3 ) b , wherein a+(2*b)=1, and wherein said transition metal (M) is Ni x Mn y Co z , wherein 0.3 ≦x ≦0.9, 0 ≦y ≦0.45, and 0 <z ≦0.4, x+y+z=1; and wherein said transition metal (M) includes further only unavoidable impurities. 2. The particulate precursor compound of claim 1 , wherein b ≦0.4. 3. The particulate precursor compound of claim 1 , wherein y=0. 4. The particulate precursor compound of claim 1 , wherein said coating layer contains non-amorphous alumina nanoparticles. 5. The particulate precursor compound of claim 1 , wherein a carbon content of said precursor compound is reduced by a heat treatment of said precursor compound at temperatures above about 400° C. reaching relatively low values at and above about 600° C. and wherein a sulfate content of said precursor compound is reduced by a heat treatment of said precursor at temperatures at and above aboutn 700° C. 6. The particulate precursor compound of claim 5 , wherein said sulfate content is lower than about 0.3 wt %. 7. The particulate precursor compound of claim 1 , wherein said precursor compound is free of crystal water. 8. The particulate precursor compound of claim 1 , wherein the coating layer has a thickness that does not change with particle size such that relatively smaller particles have a higher aluminum concentration than relatively larger particles of the same particulate precursor compound. 9. A process of preparing the particulate precursor compound of claim 1 , comprising: providing for a first quantity of alumina powder having a volume VI; providing for a first quantity of transition metal (M)-oxide, (M)-hydroxide or (M)-oxyhydroxide powder as said particulate precursor, having a volume V 2 ; mixing said first quantity of alumina powder with said first quantity of transition metal (M)-oxide, (M)-hydroxide or (M)-oxyhydroxide in a first dry-coating procedure, wherein V 1 +V 2 =V and wherein the first quantity of alumina powder and the first quantity of transition metal (M)-hydroxide or (M)-oxyhydroxide are mixed until said volume V decreases to a volume V 3 that has about the same value as VI, thereby covering a transition metal (M)-oxide, (M)-hydroxide or (M)-oxyhydroxide core with a non-amorphous aluminum oxide AI203 coating layer; and heat treating said core covered by said coating layer at a temperature in a range of about 400-800° C. 10. The process of claim 9 , wherein said heat treating is performed at a temperature in a range of about 400-600° C. 11. The process of claim 9 , further comprising heat treating said core covered by said coating layer at said temperature for duration of 5 hours or 10 hours. 12. The process of claim 9 , further comprising reducing carbon content and sulfate content of said precursor compound. 13. The process of claim 9 , further comprising obtaining an aluminum dry-coated precursor compound, wherein said core is a transition metal oxide and wherein said core is completely covered by said non-amorphous coating layer. 14. The process of claim 9 , further comprising mixing said particulate precursor compound with a lithium precursor compound and sintering the mixture.