Abstract The purpose of this study was to evaluate the effects and residual effects of high application rate of compost on the growth and nutrient uptake of rice plants. The application rate was about 10-fold as high as that in field. Four kinds of compost, (pea-rice hull compost (PRC), cattle dung-tea compost (CTC), hog dung-rice hull compost (HDR), and hog dung-sawdust compost (HDS), respectively) and two different soils (PC soil and SK soil) were used. A chemical fertilizer and a no fertilizer treatment were also contained. The soil chemical properties, rice plant growth, nutrient uptake at the different growth stages of rice plant were studied. The study was conducted through pot cultures. The effect of available nutrient concentrations in the two soils treated with the different composts were also studied through incubation. In the incubation test, each 50 gram of air-dried soil was mixed completely with appropriate amount of the four composts (6.7 g PRC; 6.6 g CTC; 6.3 g HDR and 7.5 g HDS) and chemical fertilizer (N-P-K =0.23-0.08-0.12 g kg-1) and then was placed in 100 mL beaker. The soil without any fertilizer was treated as control. After being submerged with deionized water, the soils were incubated at 25 oC for 16 weeks. The results indicated that the addition of compost to the soils increased the pH and electrical conductivity (EC) of the soils. The different effects on soil pH and EC among the four compost treatments were according to the differences in the pH and EC of the compost. The soil with addition of PRC compost had the highest pH and that of the HDS treatment had the highest EC. At the initial stage of incubation, EC of HDS treated soil reached to 4 dS m-1. The concentration of ammonium N in the soil reached the highest level after one or two weeks of incubation, and it declined gradually. The ammonium N concentrations of PRC and HDR treatments were higher than that of the other treatments, at the initial stage of incubation, and this was probably due to the high contents of easily mineralizable nitrogenous compounds. In the pot cultivation experiment of rice plants, the application rate of the composts was the same as that in the incubation study. Three kilograms of soil and appropriate amount of composts (PRC 404 g, CTC 395 g, HDR 378 g and HDS 450 g) were mixed thoroughly and packed into a 1/5000 a Wagner pot. After the harvesting of first crop, the same soils were used to study the residual effect without application of compost. However, the same rates of N and P fertilizers as applied in the first crop were applied in the second crop. All treatments were replicated four times and arranged in randomized complete block design. The nutrient concentrations of the root, leaf sheath, leaf blade, stalk, and grain were analyzed at different growth stages. The soil Eh and pH during the growth of rice plants were measured. The results showed that redox potential of the soil decreased rapidly to -200 ~-300 mV after submergence in the compost treatments. The Eh of the chemical fertilizer or no fertilizer treated-plots of PC soils decreased slowly, however, that of the SK soil decreased rapidly. At the early growth stage of rice plant, the soil of HDS treatment had a higher Eh than that of the other treatments. This indicated that biodegradation of HDS was less active than that of the other composts. In the PC soil, the dry matter yields of the CTC and HDS treated rice plants were higher than that of other treatments at the initial growth stage of the first crop. The dry matter yields of the PRC and HDR treated rice plants was lower than that of the chemical fertilizer treatment, owing to the ammonium N concentration in soil of the former treatments was higher than that of the latter. At the maturity stage, the straw yield of PRC treated rice plants was higher than that of the other treatments, and this could be attributed to the continuous release of N from the composts and beneficial to the new tiller formation at the ripening stage. In contrast to the PC soil, the dry matter yield of the chemical fertilizer treated rice plants in SK soil was higher than that of the first crop at the initial growth stage. At the maturity stage, the straw yield of the PRC treated rice plants was higher than that of the other treatments. In the second crop, the dry matter yields of PRC, CTC, and HDR treated rice plants in PC soil were higher than that of the other treatments, and this indicated that the nutrient release from the compost was enough to meet the growth demand of rice plants. However, in the SK soil, the dry matter yield of the PRC treated rice plants was relatively high, because the PRC compost still released a large amount of nitrogen and was beneficial to the growth of rice plants. The high application rate of composts resulted in the rapid soil reduction and increased the concentrations of Mn+2, ferrous ions as well as soluble aluminum ions dramtically. Nevertheless, the absorption of Mn+2, Fe+2, and Al+3 of the rice plants was not parallel to the concentrations of available Mn+2, Fe+2, and Al+3 in the soils. This could be attributed to the chelation effect of the organic matter with these metal ions. Similarly, analytical result also showed that the concentrations of Cu and Zn in the rice plants was significantly lower than that of the chemical fertilizer treated plots. Key words: rice plant, compost, growth, nutrient uptake, ammonia toxicity.