In conventional bifacial n-Si solar cells fabrication processing, raw Si wafers have to be annealed in high temperature furnace at least two times to form emitter and back surface field (BSF). However, these processing have many disadvantages and waste time in the industrial. In this thesis, we used the co-diffusion by spin-on dopants processing to form the p+ emitter and n+ BSF in the ONE step for n-type Si which could reduce the annealing time and manufacturing cost in the industrial. The two structures were fabricated to diffuse in high temperature and characterized in SIMS profiles, effective lifetime, inverse saturation current density and surface recombination velocity (SRV). Finally, the structure in highly performance for surface passivation were fabricated in bifacial n-Si solar cells in order to improve and modify the conventional manufacturing method. As our result showed, co-diffusion structure for barrier layer on phosphorous side had better surface passivation properties. This structure would be demonstrated in the bifacial n-Si solar cells for efficiency = 11.4 %, Voc = 591.6 mV, Jsc = 33.6 mA/cm2 and fill factor = 62 %.