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NCM 811 High Nickel Cathode Material Ni83 Powder ATOMFAIR®

Price range: $244.00 through $317.00

Institutional Procurement & Supply Compliance: As a verified US supplier, Atomfair accepts formal institutional Purchase Orders (POs), contract billing schedules, and custom procurement loops for university and national laboratories, and corporate R&D departments globally.

NCM 811 grade high nickel cathode powder (Ni83) with 205 mAh/g discharge capacity and 1.75 g/cm³ tap density. Research grade powder. Order now.

SKU: AFMSLZTK926
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Description

ATOMFAIR NCM (83:11:6): 205 mAh/g Cathode Active Material

RESEARCH GRADE MATERIAL

Product Overview
Engineered for advanced energy storage exploration, this premium pristine single crystal cathode active material serves as a high-fidelity benchmarking matrix for state-of-the-art electrochemical cells. By consolidating strict cell-to-cell consistency and establishing precise baseline testing control, this formula successfully drives variable elimination during critical electrolyte validation platform processing. Secure optimal institutional single crystal nmc powder price points for scaled research and high-performance development architectures.

Technical Specifications

PARAMETER DETAILS
1. Core Device & Electrochemical Design
Product Appearance Gray-black powder
Specific Surface Area (BET) 0.71 m²/g
Tap Density 1.75 g/cm³
Water Content (Moisture) 300 ppm
pH Value 11.43
Surface Residual Alkali Li₂CO₃ 0.189 %wt
Surface Residual Alkali LiOH 0.273 %wt
2. Cathode (Positive Electrode) Parameters
0.1C Discharge Specific Capacity 205.35 mAh/g (Coin Cell, 3.0V–4.3V)
3. Anode (Negative Electrode) Parameters
Testing Counter Electrode Configuration Lithium Metal Target Half-Cell Foils
4. Separator & Physical Package Metrics
Particle Size Distribution D10 2.036 μm
Particle Size Distribution D50 3.689 μm
Particle Size Distribution D90 6.712 μm
Particle Size Distribution Dmax 11.521 μm
Core Transition Metal Composition Ni: 83 %wt | Co: 11.2 %wt | Mn: 5.8 %wt
Trace Elemental Profile Ca: 0.001 %wt | Cu: 0.0001 %wt | Fe: 0.0004 %wt | Na: 0.011 %wt
Manufacturing Rules Processed under strict RoHS compliant standard conditions
Alternative Options Explore our related catalog or custom dimensions. For urgent technical custom requests or bulk inquiries, please contact our support team.


Key Features & Advantages
  • Homogeneous Material Purity: Features an uncompromised structural configuration with highly uniform elemental distribution across the single crystal matrix crystals.
  • Enhanced Operational Efficiency: Pristine single-crystal architecture exhibits remarkable intrinsic structural stability, delivering exceptional initial discharge capacity.
  • Optimized Sintering/Microstructure: Advanced synthesis allows for lower required operating temperatures and ideal grain boundary integration during testing cell fabrication.

APPLICATION SCOPE: High-nickel ternary battery prototyping, ultra-high energy density cell validation, pristine single-crystal electrochemical benchmarking, and surface-to-electrolyte interface baseline testing.
PACKAGING: Securely packed in airtight container systems to protect the specific structural stability of high-nickel matrix bands.
IMPORTANT NOTICE: This product is highly sensitive to ambient exposure. Keep containers tightly sealed or handle exclusively within an anhydrous inert gas environment to prevent phase contamination or surface residual lithium growth before thermal validation.

Frequently Asked Technical Questions

Why is ATOMFAIR NCM (83:11:6): 205 mAh/g Cathode Active Material preferred for lithium battery R&D?

ATOMFAIR NCM (83:11:6): 205 mAh/g Cathode Active Material functions as a premier high-nickel solution for next-generation cell exploration. It delivers high reversible specific capacity and excellent fundamental grain boundary structural parameters, significantly boosting performance metrics and phase purity during laboratory testing workflows.

How to minimize single crystal nmc surface residual lithium?

To successfully solve how to minimize single crystal nmc surface residual lithium without secondary contamination, this material must be handled strictly according to inert gas glovebox storage protocols before thermal processing.

How does this specific NCM cathode material compare to traditional alternative options regarding operational stability?

Compared to standard alternatives, the optimized matrix of this product incorporates specialized chemical doping. This unique architecture dramatically enhances structural resistance against degradation, preserving long-term validation integrity.

What material processing benefits does the microstructure of this NCM powder offer?

Boasting engineered particle structuring and optimized specific surface area, this product offers superior sinterability. The controlled form factor facilitates lower thermal processing thresholds and promotes ideal grain boundary integration during cell fabrication.

How is the phase purity and quality control of this research-grade batch validated?

Every competitive batch undergoes rigid analytical quality validation testing. Total elemental and metallic impurities are strictly regulated below strict industry thresholds to eliminate parasitic electronic leakage and maintain uncompromised data reproducibility.
TAILORED SOLUTIONS FOR RESEARCH
Contact our engineering team for technical support or official institutional quotations.
EMAIL: inquiry@atomfair.com
Manufacturer: Atomfair LLC
Brand: ATOMFAIR®

This material is highly moisture-sensitive and alkaline, requiring storage in an inert atmosphere to prevent surface degradation and safety hazards. Sealed packaging must remain intact until use to avoid moisture uptake and exposure to acidic or humid environments.

  • Moisture Sensitivity: Water content below 300 ppm is critical; exposure to ambient air rapidly increases surface alkali levels and degrades electrochemical performance.
  • Alkaline Nature: The high pH of 11.43 indicates strong surface alkalinity, necessitating acid-resistant containers and avoidance of contact with skin or eyes.
  • Inert Atmosphere Requirement: Storage and handling must be conducted under argon or nitrogen with less than 1 ppm moisture to prevent lithium leaching and structural damage.
  • Degradation Risk: Prolonged exposure to carbon dioxide in air can convert residual alkali into lithium carbonate, increasing impedance and reducing capacity.
  • Containment Requirement: Material must remain in factory-sealed, moisture-proof bags until transferred into a glovebox or dry room for further processing.

This procedure ensures safe transfer and preconditioning of the moisture-sensitive cathode powder for electrode fabrication. Follow each step sequentially to maintain material integrity and experimental reproducibility.

Required Equipment: Argon-filled glovebox with moisture <0.1 ppm, Vacuum oven with inert gas purge, Analytical balance (0.1 mg precision), Moisture analyzer

  1. Inspect packaging integrity
    Visually confirm the outer and inner seals are intact and undamaged before transferring to the glovebox antechamber.
  2. Transfer powder to glovebox
    Pass the sealed container through the antechamber using a standard three-cycle pump-purge process to avoid atmospheric contamination.
  3. Dry the material
    Heat the powder in a vacuum oven at 120°C for 12 hours under argon purge to remove residual moisture and surface adsorbates.
  4. Verify moisture content
    Measure a small sample using a coulometric Karl Fischer moisture analyzer to confirm water content remains below 300 ppm before electrode slurry preparation.

How does the surface residual alkali content of NCM 811 affect electrochemical performance and slurry processing?

The surface residual alkali levels of 0.189%wt Li₂CO₃ and 0.273%wt LiOH, combined with a pH of 11.43, indicate moderate alkalinity that can cause slurry gelation and coating defects if not processed in a dry environment. This alkalinity may also increase first-cycle irreversible capacity loss due to parasitic side reactions at the cathode-electrolyte interface.

What particle size distribution constraints apply when integrating NCM 811 into high-energy full cells with silicon anodes?

With a D50 of 3.689 μm and Dmax of 11.521 μm, this powder enables good rate capability but the specific surface area of 0.71 m²/g limits its compatibility with low-porosity electrode designs. For full cells with silicon anodes, the narrow particle distribution requires careful calendering to balance electrode density and electrolyte wetting without fracturing the active material.

What storage and handling infrastructure is required to maintain NCM 811 powder stability?

The powder must be stored in an inert gas atmosphere with <0.1 ppm H₂O because its high nickel content and surface residual alkalis (LiOH, Li₂CO₃) rapidly absorb moisture, increasing the already 300 ppm water content and degrading electrochemical performance. Vacuum drying at 120°C for 12 hours before use is recommended to minimize residual moisture.

This NCM 811 single crystal cathode material delivers 205.35 mAh/g at 0.1C, enabling high-fidelity benchmarking for high-energy-density Li-ion cells, but its elevated surface residual alkali and moisture content (300 ppm) demand stringent dry-room handling and slurry formulation controls.

Positive

  • High Specific Capacity: Delivers 205.35 mAh/g at 0.1C discharge (3.0–4.3V), providing a high-energy-density baseline for advanced electrolyte and cell architecture studies.
  • Single Crystal Morphology: Pristine single crystal particles reduce surface area (BET 0.71 m²/g) and minimize parasitic side reactions, enabling reliable cell-to-cell consistency in benchmarking protocols.

Trade-offs

  • Moisture Sensitivity: Water content of 300 ppm and pH of 11.43 necessitate processing in dry-room or inert-gas environments to prevent surface degradation and gas evolution.
  • Surface Residual Alkali: LiOH (0.273%wt) and Li2CO3 (0.189%wt) on particle surfaces can cause slurry gelation and coating defects, requiring optimized binder/dispersant selection and careful mixing protocols.

Every advanced material, component, equipment, and instrument in our catalog is backed by rigorous testing. We maintain strict internal quality management frameworks and align with CE conformity metrics to deliver transparent, reproducible performance data via our public open-science repository.

To request raw batch performance data, submit formal vendor registration paperwork, or execute a fast-turnaround R&D manufacturing loop, contact us at inquiry@atomfair.com.

Item is dispatched under the Atomfair Shipping & Delivery Framework (Free worldwide shipping on orders over $59 USD). Return is governed by the Atomfair Return & Refund Policy (7-day technical return window for completely unopened items).

Additional information

weight

100g, 250g

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