Polycrystalline NCM Cathode Material Description
Polycrystalline NCM Cathode Material is suitable for lithium-ion batteries for power tools and EV vehicles. The development of single crystalline particles of NCM has enabled even longer lifetimes due to achieving higher Coulomb efficiencies. Optimization of CAMs size and morphology is decisive to achieve good rate capability with high‐nickel NCMs.
Polycrystalline NCM Cathode Material Specification
Items
|
D50
(µm)
|
Tap
(g/cm3)
|
Specific Area
(m2/g)
|
Capacity
(mAh/g)
|
OH-1
Wt%
|
CO3-2
Wt%
|
Efficiency (%)
|
M1-C
|
10±2
|
≥3.4
|
0.2-0.6
|
≤0.2
|
≤0.2
|
≥180
|
≥89
|
M2-C
|
10±2
|
≥3.4
|
0.2-0.6
|
≤0.3
|
≤0.4
|
≥205
|
≥88
|
M8-C
|
10±2
|
≥3.4
|
0.2-0.6
|
≤0.3
|
≤0.6
|
≥215
|
≥88
|
Polycrystalline NCM Cathode Material Applications
It is suitable for lithium-ion batteries for power tools and EV vehicles.
Polycrystalline NCM Cathode Material Packaging
Our Polycrystalline NCM Cathode Material is carefully handled during storage and transportation to preserve the quality of our product in its original condition.
Polycrystalline NCM Cathode Material FAQs
Q1. What is Polycrystalline NCM Cathode Material?
Polycrystalline NCM (Nickel-Cobalt-Manganese) cathode material is a type of lithium-ion battery cathode made from a combination of nickel, cobalt, and manganese in a polycrystalline structure. It is widely used in rechargeable batteries due to its high energy density, stability, and long cycle life.
Q2. What are the primary uses of Polycrystalline NCM Cathode Material?
Electric Vehicles (EVs): Used in the batteries of electric cars for high energy density and long driving range.
Consumer Electronics: Employed in batteries for smartphones, laptops, and other portable devices.
Energy Storage Systems: Utilized in grid storage and renewable energy systems to store energy efficiently.
Power Tools: Integrated into batteries for cordless power tools to provide high power and long operational time.
Q3. How is Polycrystalline NCM Cathode Material produced?
It is typically produced through a co-precipitation method, where nickel, cobalt, and manganese salts are mixed and precipitated to form a precursor. This precursor is then calcined at high temperatures to form the final polycrystalline NCM structure.