TY - JOUR
T1 - Stabilization of polyacrylonitrile fibers with carbon nanotubes
AU - Lu, Mingxuan
AU - Arias-Monje, Pedro J.
AU - Ramachandran, Jyotsna
AU - Gulgunje, Prabhakar V.
AU - Luo, Jeffrey
AU - Kirmani, Mohammad Hamza
AU - Meredith, Carson
AU - Kumar, Satish
N1 - Publisher Copyright:
© 2021
PY - 2021/6
Y1 - 2021/6
N2 - Stabilization is an energy-intensive and time-consuming step for making PAN-based carbon fiber. Here, a new pathway is shown that uses carbon nanotubes (CNT) to accelerate the reaction rate and to reduce the PAN stabilization time. Bi-component core-sheath PAN-PAN/CNT (10 wt% CNT) fibers and single-component PAN/CNT (10 wt% CNT) fibers were made. When comparing to PAN fiber with comparable diameter, the heat of stabilization (ΔHreaction) of PAN/CNT fibers increased up to 3 times in the air, while it did not change in N2. The addition of CNTs reduced the activation energy (Ea) of PAN cyclization by up to 12% but increased it for the oxidation reaction by up to 80% compared to PAN fibers. CNTs did not increase the kinetic constant of the cyclization reaction but increased it for the oxidation reaction (koxidation) by up to 5 times, when comparing to PAN fiber at 250°C. At the same temperature, the bi-component PAN/CNT fiber bundle was fully stabilized in less than 2 hours, while the PAN fibers with comparable diameter took 6 hours to stabilize. Porosity was observed in the PAN/CNT precursor as well as in the stabilized PAN/CNT. This porosity was considered, at least partially responsible for increased oxygen diffusion, and hence for the decrease in the PAN stabilization time.
AB - Stabilization is an energy-intensive and time-consuming step for making PAN-based carbon fiber. Here, a new pathway is shown that uses carbon nanotubes (CNT) to accelerate the reaction rate and to reduce the PAN stabilization time. Bi-component core-sheath PAN-PAN/CNT (10 wt% CNT) fibers and single-component PAN/CNT (10 wt% CNT) fibers were made. When comparing to PAN fiber with comparable diameter, the heat of stabilization (ΔHreaction) of PAN/CNT fibers increased up to 3 times in the air, while it did not change in N2. The addition of CNTs reduced the activation energy (Ea) of PAN cyclization by up to 12% but increased it for the oxidation reaction by up to 80% compared to PAN fibers. CNTs did not increase the kinetic constant of the cyclization reaction but increased it for the oxidation reaction (koxidation) by up to 5 times, when comparing to PAN fiber at 250°C. At the same temperature, the bi-component PAN/CNT fiber bundle was fully stabilized in less than 2 hours, while the PAN fibers with comparable diameter took 6 hours to stabilize. Porosity was observed in the PAN/CNT precursor as well as in the stabilized PAN/CNT. This porosity was considered, at least partially responsible for increased oxygen diffusion, and hence for the decrease in the PAN stabilization time.
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U2 - 10.1016/j.polymdegradstab.2021.109567
DO - 10.1016/j.polymdegradstab.2021.109567
M3 - Research Article
AN - SCOPUS:85104352131
SN - 0141-3910
VL - 188
JO - Polymer Degradation and Stability
JF - Polymer Degradation and Stability
M1 - 109567
ER -