New Method Improves Strength and Modulus in Carbon Fibres

A research team at the Georgia Institute of Technology has developed a novel technique that sets a new milestone for the strength and modulus of carbon fibres.

This alternative approach is based on an innovative technique for spinning polyacrylonitrile (PAN), an organic polymer resin used to make carbon fibres. The work is part of a four-year, $9.8 million project sponsored by the Defence Advanced Research Projects Agency (DARPA) to improve the strength of carbon-fibre materials.

By using a gel-spinning technique to process polyacrylonitrile copolymer into carbon fibres, the researchers developed next-generation carbon fibres that exhibit a combination of strength and modulus not seen previously with the conventional solution-spun method.

In gel spinning, the solution is first converted to a gel; this technique binds polymer chains together and produces robust inter-chain forces that increase tensile strength. Gel spinning also increases directional orientation of fibres, which also augments strength. By contrast, in conventional solution spinning, a process developed more than 60 years ago, PAN co-polymer solution is directly converted to a solid fibre without the intermediate gel state and produces less-robust material.

The gel-spun carbon fiber produced by the team was tested at 5.5 to 5.8 gigapascals (GPa) – a measure of ultimate tensile strength – and had a tensile modulus in the 354–375 GPa range. The material was produced on a continuous carbonisation line at Georgia Tech that was constructed for this DARPA project.

Satish Kumar, a professor in the Georgia Tech School of Materials Science and Engineering who leads the project said;

This is the highest combination of strength and modulus for any continuous fibre reported to-date, and at short gauge length, fibre tensile strength was measured as high as 12.1 GPa, which is the highest tensile-strength value ever reported for a PAN-based carbon fibre.

Kumar also noted the internal structure of these gel-spun carbon fibres measured at the nanoscale showed fewer imperfections than state-of-the-art commercial carbon fibres, such as IM7. Specifically, the gel-spun fibres display a lower degree of polymer-chain entanglements than those produced by solution spinning. This smaller number of entanglements results from the fact that gel spinning uses lower concentrations of polymer than solution-spinning methods.

Kumar and his team convert the gel-spun polymer mix into carbon fibres via a selective treatment process called pyrolysis, in which the spun polymer is gradually subjected to both heat and stretching. This technique eliminates large quantities of hydrogen, oxygen, and nitrogen from the polymer, leaving mostly strength-increasing carbon.

The current performance of solution-spun PAN-based carbon fibres has been achieved after many years of material and process optimisation, yet very limited material and process optimisation studies have been carried out to date on the gel-spun PAN fibre. In the future, the researchers believe that materials and process optimisation, enhanced fibre circularity and increased solution homogeneity will further increase the strength and modulus of the gel-spinning method.