The lab scale experiments to investigate the geochemical reaction among supercritical CO2-mineral-brine which occurs at CO2 sequestration sites were performed. High pressurized cell system (100 bar and 50oC) was designed to create supercritical CO2 in the cell, simulating the sub-surface CO2 storage site. From the high pressurized cell experiment, the surface changes of Ca-feldspar, amphibole (tremolite) and olivine, resulted from the supercritical CO2-mineral-brine reaction, were observed and the dissolution of minerals into the brine was also investigated. The mineral slabs were polished and three locations on the surface were randomly selected for the image analysis of SPM and the surface roughness value (SRV) of those locations were calculated to quantify the change of mineral surface for 30 days. At a certain time interval, SPM images and SRVs of the same mineral surface were acquired. The secondary minerals precipitated on the mineral surfaces were also analyzed on SEM/EDS after the experiment. From the experiments, the average SRV of Ca-feldspar increased from 2.77 nm to 20.87 nm for 30 days, suggesting that the dissolution of Ca-feldspar occurs in active when the feldspars contact with supercritical CO2 and brine. For the amphibole, the average SRV increased from 2.54 nm to 8.31 nm and for the olivine from 0.77 nm to 11.03 nm. For the Ca-feldspar, Ca2+, Na+, Fe2+, Si4+, K+ and Mg2+ were dissolved in the highest order and Si4+, Ca2+, Fe2+ and Mg2+ for the amphibole. Fe (or Mg) - oxides were precipitated as the secondary minerals on the surfaces of amphibole and olivine after 30 days reaction. Results suggested that Ca2+, Fe2+ and Mg2+ rich minerals would be significantly weathered when it contacts with the supercritical CO2 and brine at CO2 sequestration sites.