14 Facts About Graphene electronics

Graphene electronics has been reported to be efficiently taking up cancerous cells thereby enabling the design of drug delivery agents for cancer therapy.

Graphene electronics is reported to have enhanced PCR by increasing the yield of DNA product.

Graphene electronics is so thin that water has near-perfect wetting transparency which is an important property particularly in developing bio-sensor applications.

Graphene electronics 'flying carpet' was demonstrated to deliver two anti-cancer drugs sequentially to the lung tumor cells in a mouse model.

Graphene electronics based FRET biosensors can detect DNA and the unwinding of DNA using different probes.

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Graphene electronics has a high carrier mobility, and low noise, allowing it to be used as the channel in a field-effect transistor.

Graphene electronics-based transistors could be much thinner than modern silicon devices, allowing faster and smaller configurations.

Graphene electronics reacts to the infrared spectrum at room temperature, albeit with sensitivity 100 to 1000 times too low for practical applications.

Graphene electronics has been used on different substrates such as Si, CdS and CdSe to produce Schottky junction solar cells.

Graphene electronics can be assembled into a film electrode with low roughness.

Graphene electronics could solve a major problem for fuel cells: fuel crossover that reduces efficiency and durability.

Graphene electronics-based plasmonic nano-antenna can operate efficiently at millimeter radio wavelengths.

Graphene electronics's properties suggest it as a reference material for characterizing electroconductive and transparent materials.

Graphene electronics has been used as a reinforcing agent to improve the mechanical properties of biodegradable polymeric nanocomposites for engineering bone tissue.