为探究筑坝后不同水库物理、化学、生物过程对水化学和碳循环的影响,本研究对贵州三岔河流域的平寨水库、普定水库以及猫跳河流域的红枫湖水库进行研究,于2018年3月2019年1月分别在入库河流和库区采集了分层水样和沉降颗粒物,并探究水中主要离子及颗粒物通量的时空变化特征及其控制因素.结果表明,水体主要离子的主要来源受碳酸盐溶解影响,并且离子浓度受光合作用控制.红枫湖水库水体水化学类型为Ca-Mg-HCO<sub>3</sub>-SO<sub>4</sub>型,普定水库、平寨水库水化学类型均为Ca-HCO<sub>3</sub>-SO<sub>4</sub>.夏季藻类光合作用诱导碳酸盐沉淀导致水体表层Ca<sup>2+</sup>、HCO<sub>3</sub><sup>-</sup>及溶解态Si浓度降低,其降低幅度分别为20.87%~44.25%、33.12%~51.18%、48.55%~96.34%.此外,藻类光合作用也影响C、N、Si等生源要素间的化学计量关系.Mg<sup>2+</sup>/Ca<sup>2+</sup>比值在水体垂向剖面上主要受碳酸钙沉淀的控制,而在不同水库之间则主要受流域岩性的控制.根据沉积物捕获器通量计算的平寨水库、普定水库、红枫湖水库夏季颗粒无机碳沉积通量分别为0.74、1.36、0.27 t/(km<sup>2</sup>·d),而根据水体Ca<sup>2+</sup>浓度降低计算的通量分别为0.31~0.64、0.35~0.99、0.09~0.29 t/(km<sup>2</sup>·d),根据水体HCO<sub>3</sub><sup>-</sup>浓度降低计算的通量分别为0.30~0.65、0.29~1.26、0.12~0.33 t/(km<sup>2</sup>·d).其红枫湖水库无机碳沉降通量的实测值与计算值接近,而平寨、普定水库实际沉降通量高于计算值,这可能是有外源输入导致.因此,利用水化学分层数据能对喀斯特水库中的无机碳沉降通量进行合理估算,并且能够得到较好的估算结果,从而指示碳循环的过程.;To explore the impact of changes in physical, chemical and biological processes on hydrochemistry and carbon cycle caused by damming, we investigated the flux of suspended particulate and the spatiotemporal variations of major cations and anions (Ca<sup>2+</sup>, Mg<sup>2+</sup>, Na<sup>+</sup>, K<sup>+</sup>, HCO<sub>3</sub><sup>-</sup>, SO<sub>4</sub><sup>2-</sup>, Cl<sup>-</sup>) in three karst reservoirs in Guizhou Province, i.e. Puding Reservoir, Pingzhai Reservoir, and Lake Hongfeng, for a whole hydrological year. The results showed that carbonate weathering and algae photosynthesis controlled the spatiotemporal variations of ion concentrations. The hydro-chemical type of Lake Hongfeng is Ca-Mg-HCO<sub>3</sub>-SO<sub>4</sub>, while it is Ca-HCO<sub>3</sub>-SO<sub>4</sub> in Puding Reservoir and Pingzhai Reservoir. During the summer period, as the result of carbonate precipitation induced by algae photosynthesis, the concentrations of Ca<sup>2+</sup>, HCO<sub>3</sub><sup>-</sup>, and SiO<sub>2</sub> in the surface water decreased by 20.87%-44.25%, 33.12%-51.18%, and 48.55%-96.34%, respectively. Our results also indicated that the stoichiometric relationships among C, N, Si could be affected by photosynthesis of aquatic photosynthetic organisms. Additionally, it is found that calcite precipitation regulated the Mg<sup>2+</sup>/Ca<sup>2+</sup> in water column. Finally, the inorganic carbon fluxes in summer period calculated by sediment traps were 0.74 t/(km<sup>2</sup>·d), 1.36 t/(km<sup>2</sup>·d), 0.27 t/(km<sup>2</sup>·d) for Pingzhai Reservoir, Puding Reservoir and respectively, which are comparable with the fluxes estimated by the concentration differences in Ca<sup>2+</sup> and HCO<sub>3</sub><sup>-</sup> between surface and bottom water layers. The measured fluxes of inorganic carbon in Pingzhai Reservoir and Puding Reservoir by sediment traps are higher than the calculated one, suggesting a certain amount of allochthonous inorganic carbon input due to the strong hydrological condition. Therefore, it is an alternative way to estimate the deposition flux of inorganic carbon in karst reservoirs by using vertical variations in ion concentrations in stratification period.