Product | Lithium Manganese Oxide Battery Material | |
Stock No | NS6130-02-279 | |
CAS | 12057-17-9 | Confirm |
Purity | 99.9% | Confirm |
APS | 20-40nm | Confirm |
Molecular Formula | LiMn2O4 | Confirm |
Form | Powder | Confirm |
Color | Black | Confirm |
Density | 4.1g/cm3 | Confirm |
Melting Point | >400°C | Confirm |
pH | <11 | Confirm |
Minimum Capacity | 100 mAh/g | |
Nominal capacity at 0.1C | ≥ 110 mAh/g | |
Application | Lithium Ion Power Battery Anode materials | |
Quality Control | Each Lot of was tested successfully | |
Main Inspect Verifier | Manager QC |
Assay | 99.9% |
Other Metal | 1000 ppm |
Lithium Manganese Dioxide cell chemistry is one of the first solid cathode cells commercially developed and these are still the most extensively utilized system today. These cells exhibit a remarkable shelf life, good high-rate, and low-rate capability. These cells also provide wide operation temperature range and availability in cell designs.
Lithium manganese oxide battery material: For these products the potential design-in applications are electronic, telecommunication, metering, instrumentation, office and other portable equipment use. These products exhibit outstanding cell performance and reliability, they have been able to meet and exceed the requirements of customer base worldwide.
Lithium manganese oxide with cubic spinel structure has attracted a great deal of attention. Because of its advantages like low cost, the abundance of manganese in the earth crust, environmental harmlessness and high theoretical lithiation capacity. Lithium manganese oxides (LiMn2O4) are inexpensive cathode materials and also show a high energy density, environmental acceptability, and are more abundant in nature.
Doping is supposed to be an effective path to enhance the electrochemical performance of spinel LiMn2O4, so several attempts have been made for improving the lithium manganese spinels by doping various metals ions. Lithium Manganese Oxide Battery Material an ideal material, in principle, for use in large scale batteries for powering electric vehicles (EV) or hybrid electric vehicles (HEV), but the energy density of LIBs is still too low to support their practical application.
Fabrication of high energy density LIBs requires a cathode material with high specific capacity and high density. Thus increasing the tap density of Lithium manganese oxide battery material cathode materials will be helpful to increase the energy density of LIBs.