Plant soaking decomposition as well as nitrogen and phosphorous release in the water-level fluctuation zone of the Three Gorges Reservoir

The operating scheme of the Three Gorges Reservoir results in a summer drought in the water-level fluctuation zone during which plants grow vigorously. In the winter inundation season, soaking plants may decompose and release nutrients resulting in water quality deterioration. This study quantifies the contributions of the underwater decomposition of nine dominant plant species in the water-level fluctuation zone to nutrient release. The insitu litterbag technique was used to study for soaking decomposition over 200 days. All soaking plant species decomposed rapidly at an average rate of 1.99 +/- 0.33% d(-1) in the early stage of soaking (0 to 30 days) and at an average rate of only 0.07 +/- 0.04% d-1 in the later stage (30 to 200 days). After 200 days of soaking, the nine plant species released an average of 312.40 (+/-) 39.97 g kg(-1) organic carbon, 6.71 +/- 4.29 g kg(-1) of nitrogen and 2.25 +/- 1.25 g kg(-1) of phosphorus. A positive relationship was found between soaking plant decomposition rates and initial C/N ratios of 25 to 50, and a negative relationship where the C/N ratios were between 50 and 100. The amounts of total nitrogen or total phosphorus released were significantly negatively correlated with the initial C/N or C/P ratios of the plants. Among the studied plant species, Xanthium sibiricum Patr ex Widder showed high level of nutrient release via soaking decomposition. In contrast, Cynodon dactylon (Linn.) Pers. and Polygonum hydropiper exhibited low levels of nutrient release and are recommended as suitable species for the ecological restoration of the water-level fluctuation zone. Our results demonstrate that after 200 days of soaking plant decomposition, the loadings of total organic carbon, nitrogen, and phosphorus in thewater-level fluctuation zone of the Three Gorges Reservoir were 2942.1, 81.1, and 24.7 kg ha(-1), respectively and therefore could potentially damage the aquatic environment of the reservoir. (C) 2017 Elsevier B.V. All rights reserved.