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Article Abstract
The sediment storage environment in tributaries has been altered by impoundment of water in the Three Gorges Reservoir area, affecting the distribution of phosphorus forms in sediment and processes at the sediment-water interface. Through collection of sediment and overlying water samples in Xiangxi Bay in August 2016 (before impoundment) and October (after impoundment), the distribution characteristics of sedimentary phosphorus and the environmental conditions of storage before and after impoundment were analyzed. Fluxes of PO-P at the sediment-water interface were also estimated. Results show that pH increased, alkalinity and reducibility were enhanced, and Eh in sediments decreased after impoundment. The relative content of phosphorus in sediments changed as follows:NaOH-P > HCl-P > OP to HCl-P > OP > NaOH-P; this could be attributed to changes in the depositional environment. Compared to pre-impoundment values, TP values after impoundment in sediment, overlying water (PO-P), and interstitial water (PO-P) were 1.3 times, 3.7 times, and 8.3 times higher, increasing the risk of nutrient release in sediments of Xiangxi Bay. The manifestation of PO-P in sendiments of Xiangxi River generally is "source" pre-impoundment and post-impoundment, but the PO-P diffusive flux increased from -0.0029-0.0059 mg·(m·d) pre-impoundment to 0.0067-0.1071 mg·(m·d) post-impoundment. The release of phosphorus from sediments at the bottom of Xiangxi Bay increased after impoundment.
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Article Synopsis
- The regulation of small- and medium-sized floods in the Three Gorges Reservoir has a significant impact on phytoplankton distribution in the tributaries, specifically analyzed in the Xiangxi River from 2020 to 2021.
- During flood regulation, chlorophyll a levels decreased as water levels rose, while they rebounded during reservoir impounding at the end of the flood season.
- The phytoplankton community varied with water level fluctuations, with diatoms dominating during high fluctuations and blue-green algae thriving in stable conditions, highlighting the sensitivity of algal blooms to changes in flow and suspended sediment levels.