In this study, few-layer graphene oxides were grown on mesoporous zeolite surface by thermal solvent-cracking method, regulated and catalyzed by acid functional groups. Pyrolysis of ethylene and tetrahydrofuran via chemical vapor deposition (825°С) in argon atmosphere was conducted over mesoporous zeolite nanoparticles (MZNs) as hard templates and catalysts that have intrinsic high surface area (800-900 m2/g), mesoporous (5-6 nm) and microporous (<1 nm) .Space confinement effect of micropores and Brønsted-Lowry acid of Al sites in zeolites can generate stable carbon radicals in mesoporous graphene-oxide nanoparticles (MGNs) which can be applied to photo-Fenton catalysts for organic-dye degradation, electrochemistry sensing materials after iodine doping, as well as pre-reduced electrodes as active screen-printed carbon electrodes (SPCE). The thermal solvent-cracking method has several advantages of economical carbon sources, large-scale synthesis and solvent selectivity, not only avoiding manganese contamination and pore blocking without hard-template removal but also matching principles of green chemistry, including reduced derivatives, designed degradation, and low-toxic solvent usage. Radical-based MGNs in merit of graphene-oxide growths provide alternative synthesis of photocatalysis and electrical materials.