Paddy rice is a staple food worldwide, but it accumulates As more efficiently in comparison with other cereals. Recently, rice has been considered to be a major As exposure pathway to human beings. Due to the high solubility and mobility of As under flooding conditions, and enhancing As uptake and accumulation of As by rice plants. Water management is one of the methods have been investigate to decrease As uptake by rice plants. However, water management is not always achievable, because of the growth of paddy rice is inhibited under water-deficiency conditions and the rainy weather in some area. It predicts the oxygen-releasing compounds application into paddy field may be a more efficient way to reduce As accumulation and toxicity in rice. Therefore, the objective of this study is to investigate the effect of CaO2 application on As accumulation in rice plant and arsenic species in brown rice. Pot experiments of rice growth in the greenhouse were conducted with four soils, including two geogenic As-elevated Guandu soils [GdL and GdH with low (16 mg kg-1) and high (132 mg kg-1) levels of As, respectively] and two Chiwulan soils [CaL and CaH with As-unspiked and spiked (80 mg As(V) kg-1), respectively]. CaO2 was added into soils at the application concentration of 0, 5, 10 and 20 g per kg soils and divided into separate applications. The applications were performed at 3 days before rice transplanting and the 60 days after transplanting respectively. Rice was harvested at the maturity stage. Concentrations of As, Fe and As species in soil solutions and As concentrations in different parts of rice plant were determined. The results indicate that the As and Fe concentrations in the soil solution were decreased significantly by the application of CaO2 most of the time in both incubation and pot experiments. In CaL and GdL soils, As concentration in rice roots and shoots were decreased with the increase of CaO2 application, and gives a positive influence on rice shoot biomass and grain yield. On the other hand, CaO2 application in CaH and GdH soils decreased the formation of iron plaque on the rice root thus contributed to the increase of As concentration in rice root and shoot, and declined rice shoot biomass and grain yield. Effect of CaO2 application on arsenic speciation in rice grain shows that CaO2 application leads to the decline of As(III) percentage and inorganic As concentration in brown rice in CaL and GdL soils; for CaH and GdH soils, DMA percentage decreased and there was no significant difference in inorganic As concentration in brown rice. It suggested that CaO2 might be a potential amendment to decrease As accumulation in rice at low level of As-contaminated paddy soils.