Nowadays, an important objective in managing plantation forests is the maintenance of biodiversity. As it is believed that a structurally more complex stand will harbor more diverse habitats, which in turn will promote species diversity, creating structural complexity is central to the management of plantation forests, and thinning is considered as one of the best methods to achieve that objective. Using a 10-ha sugi (Cryptomeria japonica) plantation located in central Taiwan as an example, this study intended to answer which thinning regime would create the highest structural complexity of that stand, as measured by Structural Complexity Index (SCI). Via Monte Carlo simulations, this study first investigated how a random thinning approach under three stem removal rates (20, 40, and 60%) would affect SCI. This study then proceeded to investigate how the binations of three thinning approaches(thinning-from-top, -middle, and -below) and the three stem removal rates would affect SCI. Thirdly, to mimic the effects of after-thinning understory planting on SCI, this study included Chinese-fir (Cunninghamia lanceolata) sproutings in calculating the SCI values. Finally, this study analyzed how the inclusion of topographic variations would affect SCI values. The results showed that a random thinning approach would not enhance structural complexity, and a thinning-from-middle approach would create a structurally more complex stand, due to its effects in increasing the variance of stem diameter. After-thinning understory planting would also increase structural complexity. This study showed that not all thinning regimes would promote structural complexity, some may actually reduce it, and only via detailed inventory and analysis will help us to achieve that objective.