Arsenic is a ubiquitous element in the environment. Once soil contaminated by As, it could produce health risk by food chain or leaching into the groundwater. In this study, chemical stabilization remediation technique was selected to clean up the As-contaminated soils. Chemical stabilization is the soil was added the amendments to bind or precipitate the metals to reduce the mobility or bioavailability of contaminants in the soil. Due to As is present by oxyanion in the soil which is different from the properties of general heavy metal, the soil amendments applied to heavy metal contaminated sites are doubtful for As-contaminated sites. The objectives of this study are: (1) to evaluate the risk of As in the environment by determining the water soluble As and As fractionation in soil; (2) to evaluated the effects of different chemical treatments on the As concentration of rice or Chinese cabbage grown on As-contaminated soils; and (3) to understand the relationships between the soil bioavailable As concentration and the As concentration of brown rice or Chinese cabbage. Two representative soils of Taiwan, surface soils of Jente and Pinchen soil series, were used for this study. The total As concentration of two studied soil is about 4 and 9 mg As kg-1. Soils were added with sodium arsenate (Na2HAsO4•7H2O) solution to reach the level of 0, 20, 40 mg As(V) kg-1, respectively, and then the soils were againg by cycling of drying and wetting for three months to prepare the As(V)-contaminated soils. The chemical treatments included: (1) control, (2) adding 3% compost, (3) adding 0.5% goethite, (4) adding 0.5% ferrous sulfate, (5) adding 0.5% ferrous sulfate plus calcium carbonate, and (6) adding 0.5% ferrous sulfate, 0.1% potassium permanganate and calcium carbonate. The amended soils were aging for another 3 months by cycling of drying and wetting before they were planted with rice (Oryza sativa L.). The amended soils were dried and mixed for experiments of Chinese cabbage (Brassica chinensis L. CV. Ching-Geeng). The sequential extraction procedure (SEP) of As fractionation of each treatment was conducted. The soil bioavailable concentration of As extracted by 0.1 M ammonium acetate, 0.2% ammonium citrate or 0.05 M monoammonium phosphate was analyzed to compare with the As concentrations of brown rice and Chinese cabbage. Results of Jente soil indicated that the rice growth were inhibited with increasing of soil As concentration and the rice died after transplanting two months for As-spiked 40 mg As(V) kg-1 treatment. Organic matter of compost was proposed to form the aqueous complexes with As in soil and it significantly increased the water soluble and bioavailable As concentration. The restriction of rice growth by As toxicity is also significantly found. There is no any As toxicity for Chinese cabbage growing in soil spiked with 40 mg As(V) kg-1 treatment and it decreased 67% of As concentration in the upper part of cabbage and also increased 209% of dry weight compared with the control treatment. The total As uptake per pot are not significant differences between compost and control treatment. The result of As SEP in soil showed that compost treatment can increase the non-specific bounded As fractionation and increased the health risk to the environment. Geothite treatment can only reduce the As concentration by 84% and increase the dry weight by 145% of Chinese cabbage compared with control treatment for soil-spiked with 40 mg As(V) kg-1. Ferrous sulfate treatment is the most effective amendment to reduce the As toxicity and uptake in rice, in terms of reducing the 87% of As concentration in leaf and increasing 183% of dry weight of Chinese cabbage soil-spiked with 40 mg As(V) kg-1 treatment. Ferrous sulfate treatment can reduce the non-specific bound-As fractionation which is shown the increase on the amorphous hydrous Fe and Al oxide-bounded As fraction. Ferrous sulfate treatment can adsorbe with As by forming amorphous hydrous iron oxide to reduce As risk in the environment. There are no any significant differnces between ferrous sulfate treatment and ferrous sulfate mixed with other materials such as calcium carbonate or potassium permanganate. The low bioavailable As of Pinchen soil was produced by low soil pH and high iron oxide content in soil for soil-spiked with 40 mg As(V) kg-1. The growth condition and grain production do not suffer soil As toxicity and were increasd by 328% of grain yield. As can promote the rice growth under soil-spiked with 40 mg As(V) kg-1. grain production and As concnentration of grain were not significant differences among all the tretament. The significant differences of rice growth in different soils are dependent on the iron oxide content in two soils. The soil amendments for As-contaminated soils can not only interact with As ion but also effect on the rice growth condition. It is difficult to predict the As concentration in brown rice by chemical extraction methods because the As forms in rice growing condition are not stable for As specific forms. In the upland for cabbage production, As ion was proposed as As(V) form by different extraction solutions, such as ammonium acetate, ammonium citrate and monoammonium phosphate, to satisfy predict the As concentration in Chinese cabbage by different soil amendments.