This thesis presents a comprehensive study on the CIGSSe solar cell via optimized experimental setup and parameters. The Mo bilayer had a lower sheet resistance, a better crystalline quality, and an exceptional adhesion property. Amount of Na can be controlled by varying Mo top layer structure to improve the CIGSe cell efficiency from 6.21 to 8.54 %. The CIGSe composition (Cu/(In+Ga)) at 0.95 revealed an excellent cell efficiency than the ratio of 0.75, 0.85, 1.05. The results indicated that Ga depletion at the CIGSe surface during the selenization process. To reduce the recombination at the CIGSe/CdS interface owing to Ga depletion, the CIGSe was performed by a double-graded bandgap using CuGa/In/CuGa stacked. The cell efficiency improved from 8.54 to 10.37% due to bandgap alignment. The S incorporated into the CIGSe surface contributes to a higher JSC due to the formation of hole-recombination barrier and passivation of defects after sulfurization. After sulfurization process, the VOC, JSC, FF, and efficiency increased from 0.524 to 0.564 V, 31.65 to 33.05 mA/cm2, 62.50 to 68.13, and 10.37 to 12.71%, respectively. The experimental results of CdS confirmed that the efficiency of the CIGSSe solar cell was mainly dependent on the thickness of CdS than reaction temperature during chemical bath deposition. In this thesis, the growth of CIGSSe thin films by sequential sputtering-selenization and sulfurization has been optimized with a maximum coversion efficiency of 12.71%.