Silicon solar cells have been widely used as a most promising renewable energy source due to eco-friendliness and high efficiency. As modules of silicon solar cells are connected in series for a practical electricity generation, a large voltage of 500-1,500 V is applied to the modules inevitably. Potential-induced degradation (PID), a deterioration of the efficiency and maximum power output by the continuously applied high voltage between the module frames and solar cells, has been regarded as the major cause that reduces the lifetime of silicon solar cells. In particular, the migration of the $Na^+$ 수식 이미지 ions from the front glass into Si through the anti-reflection coating and the accumulation of $Na^+$ 수식 이미지 ions at stacking faults inside Si have been reported as the reason of PID. In this research, the thickness effect of $SiO_x$ 수식 이미지 layer that can block the migration of $Na^+$ 수식 이미지 ions on the reduction of PID is investigated as it is incorporated between anti-reflection coating and p-n junction in p-type PERC solar cells. From the measurement of shunt resistance, efficiency, and maximum power output after the continuous application of 1,000 V for 96 hours, it is revealed that the thickness of $SiO_x$ 수식 이미지 layer should be larger than 7-8 nm to reduce PID effectively. potential-induced degradation;$Na^+$ 수식 이미지 ion migration;PERC;silicon solar cell;shunt resistance