Japanese government recommends leaching of soluble salts as well as adding calcium amendments for remediating saline and sodic soil after Tsunami by the earthquake on March 11, 2011,. Application of calcium carbonate (CaCO₃) is recommended for soils having pH lower than 6 and calcium sulfate (CaSO₄) is that for pH higher than 6. However, since CaCO₃ has low solubility to water, it has not been often used in reclamation of sodic soils (Shainberg et al, 1989). Solubility of CaCO3 is controlled by CO₂-H₂O-CaCO₃ equilibrium in water. The concentration of calcium ion in CaCO₃ solution is affected by CO₂ concentration (partial pressure) of air phase. The higher partial pressure of CO₂ causes the higher concentration of Ca²⁺. In general, addition of organic matter may enhance soil respiration and increase partial pressure of CO₂ in soil. This might potentially enhance solubility of CaCO₃ and increase Ca²⁺ concentration in soil solution. Increase in Ca²⁺ concentration in soil decreases exchangeable sodium percentage (ESP) of the soil. Lower ESP may inhibit soil dispersion and help to keep aggregation. Stability of aggregates has a role on soil permeability, and it affects efficiency of leaching practice. Objective of this study was to investigate the effect of changes in partial pressure of CO₂ by organic matter decomposition on dissolution of CaCO₃, and subsequent Na⁺-Ca²⁺ ion exchange of a Tsunami affected soil. Soil was collected at a former paddy field at Terashima, Miyagi, Japan, where was damaged by Tsunami at the Great East Japan Earthquake. EC (1:5) of the soil was 5.2dS m^-1. The soil was mixed with rice straw and/or CaCO₃, and then packed into plastic columns of an inner diameter of 8.5cm and 20cm-high with the bulk density of 0.95g cm^-3. Amount of rice straw and CaCO₃ application was 10t ha^-1 and 1t ha^-1, respectively. The soil columns were incubated for 23 days. During the incubation, 18mm of water was supplied for each three days. The temperature inside and around the columns, and soil water pressure were continuously monitored. The CO₂ concentration in soil air phase was measured at 5-days interval. After the incubation, the columns were leached by 4 pore volumes of 4mmol L^-1 KCl solution with. The leachate was collected for further analysis of EC, pH and concentration of cations. After the leaching, the soil columns were separated to 3cm thick layers. Each 3cm thick soil sample was used to measure EC, pH, soluble cations, and exchangeable cations of the soil. In average, soil CO₂ concentration inside the column was high under the rice straw treatment regardless of CaCO₃ application. The CO₂ concentration rose at the periodical water application, and gradually decreased with time. Rise in CO₂ concentration could be due to the enhanced organic matter decomposition and the restricted CO₂ diffusion by higher soil water content following the water application. Exchangeable cations of the column soil were measured after the leaching. Exchangeable Ca²⁺ slightly increased at whole layer of the four treatment. Increase in exchangeable K⁺ coincided with decrease in exchangeable Na⁺, suggesting ion exchange between Na⁺ and K⁺ was a dominant reaction during the leaching. In this experiment, the effect of organic matter and CaCO₃ application on remediation of the Tsunami affected saline and sodic soil was not clear. With fluctuating soil water content, soil CO₂ concentration was not always high during the column incubation experiment. It is expected that depression of soil CO₂ concentration with decrease in soil moisture after water application could not enhance dissolution of applied CaCO₃.