Hilda Zahra scite author profile

A low carbon yield is a major limitation for the use of cellulose-based filaments as carbon fiber precursors. The present study aims to investigate the use of an abundant biopolymer chitosan as a natural charring agent particularly on enhancing the carbon yield of the cellulose-derived carbon fiber. The ionic liquid 1,5-diazabicyclo[4.3.0]non-5-enium acetate ([DBNH]OAc) was used for direct dissolution of cellulose and chitosan and to spin cellulose–chitosan composite fibers through a dry-jet wet spinning process (Ioncell). The homogenous distribution and tight packing of cellulose and chitosan revealed by X-ray scattering experiments enable a synergistic interaction between the two polymers during the pyrolysis reaction, resulting in a substantial increase of the carbon yield and preservation of mechanical properties of cellulose fiber compared to other cobiopolymers such as lignin and xylan.

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Evolution of carbon nanostructure during pyrolysis of homogeneous chitosan-cellulose composite fibers

Zahra

Sawada

Kumagai

et al. 2021

Carbon

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Metal(loid) immobilization in soils with biochars pyrolyzed in N2 and CO2 environments

Igalavithana

Yang

Zahra

et al. 2018

Science of The Total Environment

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Process-dependent nanostructures of regenerated cellulose fibres revealed by small angle neutron scattering

Sawada

Nishiyama

Röder

et al. 2021

Polymer

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Evaluation of Keratin–Cellulose Blend Fibers as Precursors for Carbon Fibers

Zahra

Selinger

Sawada

et al. 2022

ACS Sustainable Chem. Eng.

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One main challenge to utilize cellulose-based fibers as the precursor for carbon fibers is their inherently low carbon yield. This study aims to evaluate the use of keratin in chicken feathers, a byproduct of the poultry industry generated in large quantities, as a natural charring agent to improve the yield of cellulose-derived carbon fibers. Keratin–cellulose composite fibers are prepared through direct dissolution of the pulp and feather keratin in the ionic liquid 1,5-diazabicyclo[4.3.0]non-5-enium acetate ([DBNH]OAc) and subsequent dry jet wet spinning (so-called Ioncell process). Thermogravimetric analysis reveals that there is an increase in the carbon yield by ∼53 wt % with 30 wt % keratin incorporation. This increase is comparable to the one observed for lignin–cellulose composite fibers, in which lignin acts as a carbon booster due to its higher carbon content. Keratin, however, reduces the mechanical properties of cellulose precursor fibers to a lesser extent than lignin. Keratin introduces nitrogen and induces the formation of pores in the precursor fibers and the resulting carbon fibers. Carbon materials derived from the keratin–cellulose composite fiber show potential for applications where nitrogen doping and pores or voids in the carbon are desirable, for example, for low-cost bio-based carbons for energy harvest or storage.

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Hilda Zahra

Close Packing of Cellulose and Chitosan in Regenerated Cellulose Fibers Improves Carbon Yield and Structural Properties of Respective Carbon Fibers

Evolution of carbon nanostructure during pyrolysis of homogeneous chitosan-cellulose composite fibers

Metal(loid) immobilization in soils with biochars pyrolyzed in N2 and CO2 environments

Process-dependent nanostructures of regenerated cellulose fibres revealed by small angle neutron scattering

Evaluation of Keratin–Cellulose Blend Fibers as Precursors for Carbon Fibers

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