50g SUPER C45 Carbon Black Conductive Additive for Battery Cathode and Anode

  • €8695

Qty (Each) Price (Each)
1 - 4 $ 89.50
5 - 9 $ 76.08
10 - 19 $ 67.13
20 - 99 $ 58.18
100 - 100+ $ 44.75

Product Name: TIMCAL SUPER C45 Carbon Black Conductive Additive for Battery Cathode and Anode 

SKU#: PO5013

Package: 50 grams per bottle (Please contact us for volume discount if you need to order a higher quantity. Bulk order will be in bulk packaging. )
CAS Number: 1333-86-4

Country of Origin: Belgium


Volatile Content

0.4 % max

Toluene Extract

0.2% max

Ash content (600°C)

0.025% max

Grit content > 45 microns / 325 mesh

<2 ppm

Grit content > 20 microns / 625 mesh

12 ppm

BET specific surface area (SSA)

45 m2/g

Particle Size 100~200 nm

Adsorption stiffness value

36 ml/5g




160 kg/m3

Sulfur Content


pH 7
Iron (Fe) 2 ppm
Nickel (Ni) 1 ppm
Vanadium (V) < 1 ppm
Chromium (Cr) < 1 ppm
Copper (Cu) < 1 ppm
Package Packaged in an air-tight container sealed in an aluminum vacuum bag

Note: Please bake the SUPER C45 carbon black powder in an oven at 150 ~ 200°C to remove absorbed moisture before using it to make slurry for coating.

The C-NERGY SUPER C45 is a high performance conductive carbon black powder made by IMERYS. SUPER C45 was introduced by IMERYS as an improved version of the SUPER P carbon black. SUPER C45 is an ultra-high purity product that has been used as a conductive additive in lithium ion battery electrodes (cathode and anode) to improve the battery performance.


a. The lowest Fe impurity level (1 ppm)

b. High specific surface area (45 m2/g)

c. Superior battery performance

The Imerys C-NERGY SUPER C45 carbon black meets the highest purity requirements for low metallic impurities and grit. The primary purpose of use of these SUPER C45 carbon black is to provide electrical conductivity to lithium-ion battery electrodes at low to very low loading.

Application Benefits:

  • Increased battery safety
  • Lower rejection ratio
  • Fully compatible with most electrolyte systems
  • No additional pre-dispersing is needed
  • No dispersing aid is needed
  • Very high loading is possible
  • Cost savings on NMP and faster drying time
  • High energy density
  • Improved power density
  • Cost reduction thanks to lower dosage needed
  • Improved flexibility of the electrode


1. Effective electrostatic confinement of polysulfides in lithium/sulfur batteries by a functional binder, Nano Energy, 2017, 40, 559-565

2. Influence of Conductive additives on the stability of red phosphorus-carbon anodes for sodium-ion batteries, Sci. Rep. 9, 946 (2019)

3. An In Situ Multiscale Study of Ion and Electron Motion in a Lithium‐Ion Battery Composite Electrode, Adv. Energy Mater.5: 1400903