(Invited) Carbon Sulfonation Using Plasma: Trial to Enlarge Treatment Capacity

Abstract

Heterogeneous catalysis is a promising technology in conversion of biomass to biofuels because of its high reactivity, easy post-separation, and great recyclability compared to homogeneous catalysis. Various functionalized catalytic materials have emerged as promising alternatives to the homogeneous liquid acid catalyst, such as carbon materials, metal–organic frameworks, and metal nanoparticles. Among them, carbon materials such as carbon nanotube, graphene oxide, carbon black, and so on have been investigated as catalysts for cellulose hydrolysis to produce glucose.Carbon materials show considerable catalytic activity by functionalization with active acidic groups including hydroxyl groups (-OH), carboxyl groups (-COOH), and sulfonic groups (-SO3H). Hydroxyl and carboxyl groups on the carbon catalysts act as connection center to access cellulose, where sulfonic group serves as the active site to cut off the linkage between glucose units in cellulose. So, the surface modification of carbon materials with these functional groups, namely, carbon sulfonation process, becomes the determining step to producing efficient carbon acid catalysts. Conventional methods for the carbon sulfonation are the hydrothermal and reflux method, in which hazardous chemicals are necessary, such as concentrated sulfuric acid (95–98%), chlorosulfonic acid, fuming sulfuric acid, or 4-benzenediazoniumsulfonate under elevated temperature for dozens of hours.As a green and effective carbon sulfonation process, we have utilized plasma generated in contact with dilute sulfuric acid. Recently, we have investigated the mechanism of carbon sulfonation in GLIP processes. Active species produced near the gas–liquid interface such as •OH, SO3, and HOSO2• probably play important roles in carbon sulfonation. We are currently trying to enlarge the treatment capacity of carbon sulfonation by two methods, namely parallel plasma generation with ballast capacitors and large-area plasma generation by a dielectric barrier discharge. Also, effects of gases used for plasma generation such as air and Ar on the carbon sulfonation are investigated.This work was partially supported by the Environment Research and Technology Development Fund (JPMEERF20223R01) of the Environmental Restoration and Conservation Agency of Japan.