Abstract
An electrosynthesis is presented to transform CO2 into an unusual nano and micron dimensioned morphology of carbon, termed Carbon Nano-Scaffold (CNS) with wide a range of high surface area graphene potential usages including batteries, supercapacitors, compression devices, electromagnetic wave shielding and sensors. Current CNS value is over $323 per milligram. The morphology consists of a series of asymmetric 20 to 100 nm thick flat multilayer graphene platelets 2 to 20 µm long orthogonally oriented in a 3D neoplasticism-like geometry, and appears distinct from the honeycomb, foam, or balsa wood cell structures previously attributed to carbon scaffolds. The CNS synthesis splits CO2 by electrolysis in molten carbonate and has a carbon negative footprint. It is observed that transition metal nucleated, high yield growth of carbon nanotubes (CNTs) is inhibited in electrolytes containing over 50 wt% of sodium or 30 wt% of potassium carbonate, or at electrolysis temperatures less than 700 °C. Here, it is found that a lower temperature of synthesis, lower concentrations of lithium carbonate, and higher current density promotes CNS growth while suppressing CNT growth. Electrolyte conditions of 50 wt% sodium carbonate relative to lithium carbonate at an electrolysis temperature of 670 °C produced over 80% of the CNS desired product at 85% faradaic efficiency with a Muntz brass cathode and an Inconel anode.
Highlights
An electrosynthesis is presented to transform CO2 into an unusual nano and micron dimensioned morphology of carbon, termed Carbon Nano-Scaffold (CNS) with wide a range of high surface area graphene potential usages including batteries, supercapacitors, compression devices, electromagnetic wave shielding and sensors
Rather than emitting CO2, this new electrosynthetic methodology uses C O2 as a reactant and is carbon negative. This is especially true if one uses renewable energy as source of electricity; even with fossil fuels energy this may be true[27,28,29]. This is because all fossil fuels, with exception of coal, get energy from hydrogen and carbon combustion with extra energy form burning hydrogen part of hydrocarbon leading to some cases a net negative carbon footprint as seen for some carbon nanotubes (CNTs) production we have done in the past[27,28]
In the C2CNT process, we have demonstrated and quantified the affinity of molten carbonates to absorb both atmospheric and flue gas levels of CO2, and have utilized 13C isotope C O2 to t rack[37] and demonstrate in molten lithium carbonate that CO2 originating from the gas phase serves as the renewable carbon building blocks in the observed CNT product and the net reaction is in accord with: Dissolution : CO2 gas + Li2O soluble, produced by electrolysis ⇋ Li2CO3(molten)
Summary
An electrosynthesis is presented to transform CO2 into an unusual nano and micron dimensioned morphology of carbon, termed Carbon Nano-Scaffold (CNS) with wide a range of high surface area graphene potential usages including batteries, supercapacitors, compression devices, electromagnetic wave shielding and sensors. As described here the successful molten carbonate CO2 electrolysis to the unusual morphology, new CNS product occurs by conducting the electrolysis in electrolytic conditions not conducive to CNT formation (inhibiting nucleation points) consisting of electrolytes with decreased lithium concentration, and either at lower temperatures or at higher electrolysis current density.
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