Nanoscale pore structure cathode for high power applications and material synthesis methods

The invention claimed is: 1. A lithium iron phosphate electrochemically active material for use in an electrode in an electrochemical energy storage device, comprising: a phosphorus to iron molar ratio of 1.000-1.050:1; a dopant comprising vanadium and a co-dopant comprising cobalt; and a total non-lithium metal to phosphate molar ratio of 1.000-1.040:1, wherein the lithium iron phosphate electrochemically active material is in the form of primary and secondary particles having respective pore structures, such that the lithium iron phosphate electrochemically active material has a bimodal pore size distribution, wherein the bimodal pore size distribution has a first pore volume at a first pore width of about 2.5 nm, the first pore volume being larger than a pore volume of a lithium iron phosphate synthesized from a spheniscidite precursor at the first pore width, and wherein the lithium iron phosphate electrochemically active material is not synthesized from the spheniscidite precursor. 2. The lithium iron phosphate electrochemically active material of claim 1 , wherein the lithium iron phosphate electrochemically active material corresponds to a formula of Li z Fe (1-x-y) V x Co y PO 4 , where x is greater than 0, y is greater than 0, and z is greater than or equal to 1. 3. The lithium iron phosphate electrochemically active material of claim 1 , wherein the vanadium is contributed by a first oxyanion species for which the vanadium is considered a cation, and where the cobalt is contributed by a second oxyanion species for which the cobalt is considered a cation. 4. The lithium iron phosphate electrochemically active material of claim 1 , wherein the vanadium is contributed by an oxyanion species, where the oxyanion species is vanadium phosphate (VPO 4 ), ammonium metavanadate (NH 4 VO 3 ), or a combination of the two, and where the vanadium dopant is in a trivalent state. 5. The lithium iron phosphate electrochemically active material of claim 1 , wherein the lithium iron phosphate electrochemically active material comprises a surface area of 25 to 35 m 2 /g. 6. The lithium iron phosphate electrochemically active material of claim 5 , wherein the surface area is contributed by the primary and secondary particles with the respective pore structures. 7. The lithium iron phosphate electrochemically active material of claim 6 , wherein a particle diameter of the primary particles is between 25 and 150 nm. 8. The lithium iron phosphate electrochemically active material of claim 6 , wherein a particle diameter of the primary particles is less than 80 nm. 9. The lithium iron phosphate electrochemically active material of claim 6 , wherein greater than 50% of a pore volume of the pore structures is attributed to pores less than 15 nm in diameter. 10. The lithium iron phosphate electrochemically active material of claim 1 , wherein the total non-lithium metal to phosphate molar ratio is 1.001-1.020:1. 11. The lithium iron phosphate electrochemically active material of claim 1 , wherein the lithium iron phosphate electrochemically active material is synthesized from a pure-phase FePO 4 precursor. 12. The lithium iron phosphate electrochemically active material of claim 1 , wherein a moisture uptake of the lithium iron phosphate electrochemically active material is lower than a moisture uptake of the lithium iron phosphate synthesized from the spheniscidite precursor. 13. The lithium iron phosphate electrochemically active material of claim 1 , wherein the first pore volume is about 0.003-0.004 cm 3 /(g·nm). 14. The lithium iron phosphate electrochemically active material of claim 1 , wherein the bimodal pore size distribution has a second pore volume at a second pore width of about 20 nm, the second pore volume being smaller than a pore volume of the lithium iron phosphate synthesized from the spheniscidite precursor at the second pore width. 15. The lithium iron phosphate electrochemically active material of claim 14 , wherein the second pore volume is less than about 0.001 cm 3 /(g·nm).