Carbon Fibers from Wet-Spun Cellulose-Lignin Precursors Using the Cold Alkali Process
Andreas Bengtsson,
Alice Landmér,
Lars Norberg,
Shun Yu,
Monica Ek,
Elisabet Brännvall,
Maria Sedin
Affiliations
Andreas Bengtsson
RISE Research Institutes of Sweden, Division Bioeconomy and Health, Materials and Surface Design, Drottning Kristinas väg 61, SE-114 28 Stockholm, Sweden
Alice Landmér
RISE Research Institutes of Sweden, Division Bioeconomy and Health, Materials and Surface Design, Drottning Kristinas väg 61, SE-114 28 Stockholm, Sweden
Lars Norberg
RISE Research Institutes of Sweden, Division Bioeconomy and Health, Materials and Surface Design, Drottning Kristinas väg 61, SE-114 28 Stockholm, Sweden
Shun Yu
RISE Research Institutes of Sweden, Division Bioeconomy and Health, Materials and Surface Design, Drottning Kristinas väg 61, SE-114 28 Stockholm, Sweden
Monica Ek
Department of Fiber and Polymer Technology, School of Engineering Sciences in Chemistry, Biotechnology and Health, KTH Royal Institute of Technology, SE-100 44 Stockholm, Sweden
Elisabet Brännvall
Department of Engineering Pedagogics, School of Engineering Sciences in Chemistry, Biotechnology and Health, KTH Royal Institute of Technology, SE-100 44 Stockholm, Sweden
Maria Sedin
RISE Research Institutes of Sweden, Division Bioeconomy and Health, Materials and Surface Design, Drottning Kristinas väg 61, SE-114 28 Stockholm, Sweden
In recent years, there has been extensive research into the development of cheaper and more sustainable carbon fiber (CF) precursors, and air-gap-spun cellulose-lignin precursors have gained considerable attention where ionic liquids have been used for the co-dissolution of cellulose and lignin. However, ionic liquids are expensive and difficult to recycle. In the present work, an aqueous solvent system, cold alkali, was used to prepare cellulose-lignin CF precursors by wet spinning solutions containing co-dissolved dissolving-grade kraft pulp and softwood kraft lignin. Precursors containing up to 30 wt% lignin were successfully spun using two different coagulation bath compositions, where one of them introduced a flame retardant into the precursor to increase the CF conversion yield. The precursors were converted to CFs via batchwise and continuous conversion. The precursor and conversion conditions had a significant effect on the conversion yield (12–44 wt%), the Young’s modulus (33–77 GPa), and the tensile strength (0.48–1.17 GPa), while the precursor morphology was preserved. Structural characterization of the precursors and CFs showed that a more oriented and crystalline precursor gave a more ordered CF structure with higher tensile properties. The continuous conversion trials highlighted the importance of tension control to increase the mechanical properties of the CFs.
