Biochar (BC) is a byproduct from biomass pyrolysis or gasification which used to produce biofuels. Recent studies have indicated that application of biochar to soils results in reducing greenhouse gas (GHG) emissions from soil, increasing soil carbon sequestration, and improving crop yields. Besides, biochar production could indirectly solve energy and biomass wastes problems. The objectives of this study were first to develop a method to measure greenhouse gas emissions from soil in a pot experiment, and then to examine the effects of biochar application on (1) greenhouse gas emissions from soils, (2) soil carbon sequestration, and (3) crop growth and yield in pot experiments. Biochars were produced at 290 (BC290) and 700℃ (BC700) by slow pyrolysis of Japanese Cedar woodchip thinned from plantation. The acidic Pinchen series (Pc) and alkaline Hoshin series (Hb) soils in Taiwan were selected to be planted with rice and leaf beet, and applied with BC290 or BC700 at a rate of 2% or 5% with or without fertilizers. There were six treatments in this study: (1) BK1 (Control I): applying 0% BC without fertilizer, (2) BK2 (Control II): applying 0% BC with fertilizers (1 g N - 1 g P - 1 g K for rice or 0.5 g N - 0.1 g P- 0.4 g K for leaf beet), (3) BC290-2%: applying 2% BC290 with fertilizers, (4) BC290-5%: applying 5% BC290 with fertilizers, (5) BC700-2%: applying 2% BC700 with fertilizers, and (6) BC700-5%: applying 5% BC700 with fertilizers, and triplicates for each treatment. Pot experiments were started on April 5, 2011. GHG emissions were monitored using closed chamber method during the rice and leaf beet growing periods and further calculated in carbon dioxide equivalent (CO2e). Carbon sequestrations were estimated from the differences between carbon addition (biochar-C) and carbon loss (CO2-C). Soils were sampled periodically and analyzed pH, CEC, available phosphorous, available potassium, total nitrogen, and organic carbon contents. Plant growth (plant height and tiller number) of rice and leaf beet were measured weekly and grain yields or dry matter weights were also measured after harvesting. The method for measuring greenhouse gas emissions from soil in a pot experiment was newly developed and used in this study, and could also be used in other related studies. The results of pot experiments showed that applying 5% BC700 significantly reduced cumulative CO2e emissions from both rice-planted Pc and Hb soils, and applying 2% BC700 significantly reduced cumulative CO2e emission from leaf beet-planted Pc soil compared with control II (p < 0.05). For soil carbon sequestration, the effects of applying 5% BC700 were the most significant in both rice- and leaf beet-planted soils (p < 0.05). As for crop growth and yield, there were no significant effects among all treatments with fertilizers (p > 0.05).