Graphene, a free-standing 2D material, has a lot of special properties. Benefitting by this single-atom-layer structure, the graphene film is very sensitive, possessing the potential to be modified with chemical dopants. Besides the tunable work function, its high transparency and conductivity make it a promising material to replace metal electrode in Schottky junction solar cell. In the first part of this thesis, a method of bifacial modification is applied to play with the two surface of graphene. With modifying the bottom side of graphene with gold nanoparticles, the contact between graphene and silicon can be improved. Then along with top doping by bis(trifluoromethanesulfonyl)amide (TFSA), the two surfaces of graphene can both be treated. The final bifacially modified device reaches a high power conversion efficiency (PCE) of 11.8%. In the second part, a solution method based on simple oxidation-reduction reaction is derived to fill the cracks of graphene with gold particles. The PCE of Au-filled graphene-Si Schottky junction photovoltaic with TFSA doping reaches the highest value (12.2%) of this junction without antireflection technique to date, and its high fill factor (78.8%) is even close to the performance of conventional silicon p-n junction solar cell.