NanoSilC - Unique 3-D NanoCarbon Materials
NanoSilC - 3 D NanoCarbon

SCNTE's CTCC process enables the production of CNT yarns containing
thousands of tow at a time without delicate and tedious spinning technology.
This gives SCNTE and our partners a significant production advantage over
competitive CVD technologies requiring spinning.
Carbo Thermal Carbide Conversion. SCNTE LLC utilizes a proprietary nanocarbon
production process that uses high temperature (over 1900C) and tightly controlled
reactive gases to convert high purity carbides into nanocarbon materials with
superior electrochemical properties.

In fact, SCNTE LLC is the only manufacturer of
electronic and electrochemical
grade nanocarbon material.
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carbon, nano, CNT, swcnt, li, edge plane, arrays,
bulk, chirality, batteries, sensors, capacitors, carbon
nanotube, swcnt, mwcnt, graphene, lithium, sodium,
electrochemical, sensor, catalyst, cvd
carbon, nano, CNT, swcnt, li, edge plane, arrays,
bulk, chirality, batteries, sensors, capacitors, carbon
nanotube, swcnt, mwcnt, graphene, lithium, sodium,
electrochemical, sensor, catalyst, cvd
carbon, nano, CNT, swcnt, li, edge plane, arrays,
bulk, chirality, batteries, sensors, capacitors, carbon
nanotube, swcnt, mwcnt, graphene, lithium, sodium,
electrochemical, sensor, catalyst, cvd
Sustainable Carbon NanoTechnology and Engineering LLC
Engineered NanoCarbon Materials for Power Storage and Transmission                       
Low Magnification SEM Image of NanoSilC
Low Magnification SEM Image of NanoSilC
Medium magnification SEM image of a broken end of NanoSilC material.
This image, and those below, show the unique composition of NanoSilC.
Ideal for fabricating buckypaper, cloth electrodes, and active filtration
products, NanoSilC retains the superior properties of the CTCC
process:
  • Metal catalyst free
  • Lengths up to 500m
  • Environmentally sound chemistry
  • Ultra high edge plane character
  • Consistent and reliable performance
NanoSilC material undergoing Focused Ion Beam milling to thin a
section for TEM imaging. Note the ultra high, electrochemically active
surface area, ideal for energy storage
via Electrochemical Double
Layer Capacitance and lithium-ion storage.

NanoSilC addresses multiple energy storage application issues with 1-
D and 2-D nanocarbon -
  • Lack of residual catalyst minimizes impurities generated for
    EDLCs
  • Clean electrochemistry allows consistent Li performance
  • The interlinked nanostructures and microstructure ensure the
    lowest internal resistance possible
When compared with conventional CNT yarns, NanoSilC has superior
electrochemical and chemical potential. CVD grown CNT yarns are
predominately side wall, and thus basal plane character. This severely
limits their ability to preform in energy storage and other
electrochemical applications.
The sub structure of NanoSilC. Tightly nested 3-Dimensional networks
of catalyst free, ultra high edge plane character nanocarbon.

The
NanoSilC advantage.
Contact:
info@scnte.com
Phone: 937.602.4544
7278 North US68
Wilmington, OH 45177