Technology

Nanocomposite technology for precision material control.

Elect Nano nanocomposite materials are designed to deliver precise control over electromagnetic, electrostatic, and optical properties that legacy materials often struggle to achieve.

Explore Discrete CNTs

Technology areas

A platform built around dispersion, interface chemistry, and application fit.

Most composites start with the filler and assume the properties follow. Elect Nano starts with the target — the resistance window, the shielding level, the reflectance threshold — and engineers the dispersion, surface chemistry, and matrix to hit it. Each technology area below covers a specific property domain.

Nanocarbon platform

Discrete CNTs

Elect Nano separates bundled carbon nanotubes into discrete structures, then uses surface chemistry to help those structures integrate into polymers, coatings, adhesives, and specialty material formats.

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Electrostatic performance

ESD Control

Discrete CNT networks can support electrostatic control at low loading levels while preserving processability, surface finish, laser marking, and part design freedom.

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Electromagnetic management

EMI Shielding

Elect Nano engineers conductive nanocomposites and hybrid filler systems for high-level EMI shielding where the priority is reducing transmission through the material or enclosure.

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Loss and attenuation

EMI Absorption

Engineered nanofiller systems can tune dielectric loss, conductive loss, optional magnetic loss, and impedance matching where absorption, frequency band, thickness, and package constraints must be balanced.

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Optical control

Optical Coatings

Elect Nano develops nanocarbon coating systems for surfaces where reflectance control, spectral absorption, coating thickness, adhesion, handling, and substrate compatibility matter.

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Technology model

Legacy filled materials often trade one property problem for another.

Nanocomposite engineering is about controlling dispersion, interface chemistry, and loading so electrical, RF, optical, mechanical, and processing requirements can be balanced instead of treated as isolated targets.

Discrete CNT platform

Carbon nanotubes are discretized and functionalized so they can be dispersed into practical material formats.

Property targeting

Material development is organized around electrostatic, electromagnetic, RF, optical, thermal, mechanical, and processing targets.

Matrix compatibility

Functionalization is matched to the host polymer, coating, adhesive, or carrier so the interface supports the final application.

Usable material formats

Technology is translated into compounds, coatings, adhesives, dispersions, masterbatches, coupons, and sample lots.

Application testing

Performance claims are tied to customer test methods, geometry, processing requirements, and qualification constraints.

Path to scale

Development moves from screening to repeatable sample preparation and production-oriented material formats.

Surface chemistry

Functional groups are selected around the host material so the nanocarbon surface contributes to dispersion, stability, and final performance.

Uniform dispersion

Discrete CNT systems are developed to reduce agglomeration and help properties distribute more consistently through the material.

Customer validation

Candidate materials are evaluated through practical samples, target test methods, application requirements, and scale-up constraints.

Material sample review

Bring a demanding material problem to Elect Nano.

Elect Nano can help translate performance targets into a sample plan, test path, and material candidate set.

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