不同干燥方式对湖泊沉积物磷提取的影响   总被引：1，自引：0，他引：1  

张润宇  王立英  刘超  朱淮武 《矿物学报》2012,32(3):417-424

以滇池5个典型区域表层沉积物为例,研究了自然风干、低温烘干和真空冻干等3种干燥方式对沉积物中磷的形态含量及其生物有效性测定的影响。结果表明：烘干、风干过程促进了沉积物有机磷的降解转化和微生物磷的释放,导致有机磷的含量偏低,总磷含量却比冻干高。各形态磷受不同干燥方式的影响程度不同,风干样品中BD-P较高,冻干样品中NaOH-rP含量最高,NH4Cl-P、HCl-P、残渣磷（Residual-P）由于含量较低或其化学性质比较稳定而差异不大。冻干样品中生物可利用磷分别比风干、烘干高26.7%、20.2%,表明冻干处理能较为真实地反映沉积物中磷的组成特征,是比较理想的样品干燥方式。各形态含量顺序为：藻类可利用磷（AAP）〉NaHCO3可提取磷（Olsen-P）〉水溶性磷（WSP）〉易解吸磷（RDP）。沉积物中Olsen-P与NH4Cl-P、BD-P、NaOH-rP、活性磷及上覆水体总磷水平呈显著正相关,因此可作为评价滇池沉积物磷的生物有效性的重要指标。  相似文献   

Variations in the depth distribution of phosphorus in soil profiles and implications for model-based catchment-scale predictions of phosphorus delivery to surface waters     

P.N. Owens  L.K. Deeks  G.A. Wood  M.J. Betson  E.I. Lord  P.S. Davison 《Journal of Hydrology》2008,350(3-4):317-328

The PSYCHIC process-based model for predicting sediment and phosphorus (P) transfer within catchments uses spatial data on soil-P derived from the National Soil Inventory (NSI) data set. These soil-P values are based on bulked 0–15 cm depth and do not account for variations in soil-P with depth. We describe the depth distribution of soil-P (total and Olsen) in grassland and arable soils for the dominant soil types in the two PSYCHIC study catchments: the Avon and the Wye, UK. There were clear variations in soil-P (particularly Olsen-P) concentrations with depth in untilled grassland soils while concentrations of total-P were broadly constant within the plough layer of arable soils. Concentrations of Olsen-P in arable soils, however, exhibited maximum values near the soil surface reflecting surface applications of fertilisers and manures between consecutive ploughing events. When the soil-P concentrations for the surface soil (0–5 cm average) were compared to both the profile-averaged (0–15 cm) and the NSI (0–15 cm) values, those for the surface soil were considerably greater than those for the average 0–15 cm depth. Modelled estimates of P loss using the depth-weighted average soil-P concentrations for the 0–5 cm depth layer were up to 14% greater than those based on the NSI data set due to the preferential accumulation of P at the soil surface. These findings have important implications for the use of soil-P data (and other data) in models to predict P losses from land to water and the interpretation of these predictions for river basin management.  相似文献