Forest plant diversity is the basis of many ecological services. Thus understanding forest plant diversity for the purpose of conservation, management, and sustainable use becomes an important topic for many ecologists. Tree tagging and tree aboveground biomass are often used as indicators to examine the quality of a forest. Tree tagging shows the overall distribution of the tree species, while aboveground biomass is an important carbon pool in the forest ecosystem. In this study, 102 sampling sites were randomly chosen in the Lienhuachih Forest Dynamic Plot in Nanto, Taiwan. In each sampling site, 0-5 and 5-15 cm soil were collected, and soil pH, soil organic matter (SOM), electrical conductivity (EC), cation exchange capacity (CEC), available potassium and phosphorous, ammonium nitrogen (NH4-N), nitrate nitrogen (NO3-N), exchangeable calcium, magnesium and potassium, and water holding capacity (WHC) were measured. Species richness, abundance, and aboveground biomass were calculated within the circle of 10 m radius around the sampling site to study the effect of soil properties of different soil layers and topography on tree distribution. The results of multiple regression showed that 0-5 cm soil explained more variation in aboveground biomass, while 5-15 cm soil explained more variation in tree species richness and abundance. Redundancy analysis showed that 5-15 cm soil exerted a greater overall influence on species distribution and aboveground biomass. The influence of 0-5 cm soil was mostly associated with SOM, while the influence of 5-15 cm soil was mostly associated with CEC and EC. Overall, SOM contributes to the nutrient availability of 0-5 cm soil, and the available nutrient contents directly affect aboveground biomass. The CEC of 5-15 cm soil becomes an important factor in determining the availability of certain nutrients leached from 0-5 cm soil. Thus the presence and absence of certain nutrients in 5-15 cm soil might favor the growth of certain tree species, and CEC subsequently shapes the overall species distribution and contribute to the stability of soil-tree species relationship.