This study is to investigate radiation energy variation and soil thermal properties in forest area. Experimental plot was selected in Lienhuachi experimental watershed No. 5. Radiometer, heat flux plate, and soil thermometers and tensiometers embedding at different depths were set. Data involving net radiation, soil temperature, and soil water potential were collected during May 2005 to April 2006. From analyzed data, the characteristics of net radiation within and without the forest, soil temperature, and soil thermal change with soil water situation were understood. Results are summarized as follows: Decreasing solar radiation, decreasing air temperature, and defoliation during winter could cause earth radiation emission through out the canopy. Therefore, the net radiation ratio of within the forest to without the forest was lower. In summer, more latent heat flux and sensible heat flux caused relatively less proportion of soil heat flux to net radiation within the forest. In winter, latent heat flux and sensible heat flux were less than other seasons. Besides, soil heat flux became heat source of earth surface that could increase the proportion to net radiation. Daily soil temperature variation at the shallow part of soil appeared in sine curve. The amplitude of sine curve was decreasing with soil depth increasing. Also, the start of sine curve period delayed with soil depth increasing. During September to October 2005, the overturn of soil temperature occurred, soil heat from endothermic state converted to exothermic state. The process reverted to original state during March to April 2006. Among the rainfall occurred, it was therefore fair that soil water potential at the shallow part changed fastest. In gravitational water condition (pF value below 1.8) and in mobile capillary water condition, soil thermal conductivity would be significantly negative correlation with soil water potential, but in non-mobile capillary water condition, soil thermal conductivity would not be significantly correlation with soil water potential. The mean of the soil thermal conductivity obtained from non-organic matter covered surface was 1.095 Jm-1℃-1S-1, and that of the organic matter covered soils was 0.5736 Jm-1℃-1S-1. Furthermore, the daily variation amplitude of the soil thermal conductivity obtained from non-organic matter covered surface was larger than that of the organic matter covered surface.