Sulfur-doped carbon nanotubes as a conducting agent in supercapacitor electrodes

The electrochemical performance of sulfur-doped carbon nanotubes (S-CNTs) was investigated to confirm the S-doping effects and the possibility of their application as conducting agents in supercapacitor electrodes. S-CNTs were successfully synthesized via chemical vapor deposition using dimethyl disulfide as the carbon source. They were purified to obtain purified S-CNTs (P-S-CNTs) with diameters 30-50 nm and S content of 0.65 at%. The doped S atoms were removed partially from the P-S-CNTs by heat treatment in H-2 atmosphere (De-P-S-CNTs). To compare the electrochemical performances of various conducting materials for supercapacitor electrodes, commercial activated carbon (MSP20) was used as the active material and commercial conducting agent (Super-P), commercial multi-walled CNTs (MWCNTs), De-P-S-CNTs, and P-S-CNTs were used as the conducting agents. The electrode with P-SCNTs exhibited the highest specific capacitance at a high discharge current density of 100 mA cm(-2) (120.2 F g(-1)) and the lowest charge-transfer resistance (6.19 Omega) that are significantly superior to those of Super-P (83.9 F g(-1) and 15.16 Omega), MWCNTs (87.8 F g(-1) and 17.02 Omega), and De-P-S-CNTs (90.1 F g(-1) and 22.33 Omega). The superior electrochemical performance of P-S-CNTs can be attributed to the excellent electrical conductivity and pseudocapacitive contribution of the S-doping effect. (C) 2020 Elsevier B.V. All rights reserved.

Automated summary

The electrochemical performance of sulfur-doped carbon nanotubes (S-CNTs) was investigated, confirming their potential as conducting agents in supercapacitor electrodes. The purified S-CNTs (P-S-CNTs) showed superior specific capacitance and lower charge-transfer resistance compared to other conducting materials. The excellent performance of P-S-CNTs is attributed to their electrical conductivity and sulfur-doping effects.