Litcius/Paper detail

Coal pitch-based nanosheets enhance the electronic and ionic transport of flow electrode capacitive deionization

Jincai Ran, Zhaoyang Song, Qiongqiong He, Zhenyong Miao

2025International Journal of Mining Science and Technology9 citationsDOIOpen Access PDF

Abstract

High-salinity wastewater treatment has always been a challenging issue. In this study, coal tar pitch was used as the carbon source and melamine as the nitrogen source to prepare coal tar pitch-based nanosheets (CPN-9) using a salt-template method. The desalination performance of CPN-9 was evaluated using flow-electrode capacitive deionization technology. The results showed that CPN-9 has a high specific surface area (466.34 m 2 /g), a rich pore structure (micro-/ meso -pore volume was 0.28), excellent rheological properties, and hydrophilicity (contact angle of 20.44°), thereby accelerating ion transport. Electrochemical results indicated that CPN-9 exhibits a significant double-layer ion storage mechanism, with a specific capacitance of 176.66 F/g at a current density of 0.5 A/g. CPN-9 has a very low charge transfer resistance. The synergistic effect of aromatic carbon and nitrogen doping (the content of pyrrole and pyridine nitrogen was 36.40% and 35.83%, respectively) in coal tar pitch accelerates electron transfer in CPN-9. The good ion diffusion performance and low impedance of CPN-9 accelerate the ion exchange rate, resulting in outstanding desalination performance. At 1.2 V and 3% mass loading, with a CPN-9 to conductive carbon black ratio of 4:1, the average desalination rate, charge efficiency, and energy consumption reached 0.039 mg/(cm 2 ·min), 48.47%, and 0.012 kWh/mol, respectively. In summary, this study optimized the structure of CPN-9 from the perspective of electronic and ionic transport, enhancing its desalination performance and providing theoretical support for the deionization of high-salinity wastewater.

Topics & Concepts

Capacitive deionizationElectrodeIonic bondingCapacitive sensingCoalMaterials scienceChemical engineeringIonEngineeringChemistryWaste managementElectrical engineeringElectrochemistryOrganic chemistryPhysical chemistryMembrane-based Ion Separation TechniquesSupercapacitor Materials and FabricationAdvanced battery technologies research