Self-assembly synthesis of mesoporous zeolite nanoparticles (MZNs) with high surface area (800-900 m2/g), uniform mesopores (5-6 nm), and crystalline-induced micropores (<1 nm) have been developed for enhanced hydrothermal stability as well as space-confinement substrates toward adsorption and catalysis purposes. Adsorption applications can be conducted by surface-modified MZNs with organolithium reagents. The captured CO2 results in Li2CO3 products, spatially-confined in the mesopores for recycling and reusing purposes. Mesoporous graphene-oxide zeolite nanoparticles (MGNs) are synthesized via one-step chemical vapor deposition (CVD) method. Ethylene, the only carbon source, was decomposed at high temperature and then deposited onto MZNs, forming single and few-layer graphene oxide with retention of original mesoporosity. The evidence of graphene oxide layers is revealed by photoluminescence, UV-Vis absorption, Raman, XPS and XRD spectroscopies. Efficient adsorption of R6G and metal ions was due to the high surface area and the graphene-oxide properties in MGNs. The free radicals in MGNs also induce Fenton-like reaction that decomposes organic compounds for catalysis purposes.