Su Jingjun, Wang Hailong, Kimberley Mark O, Beecroft Katie, Magesan Guna N, Hu Chengxiao
College of Resources and Environment, Huazhong Agricultural University, Wuhan, 430070, China.
Environ Sci Pollut Res Int. 2007 Nov;14(7):529-35. doi: 10.1065/espr2007.08.443.
GOAL, SCOPE AND BACKGROUND: Biosolids, i.e., treated sewage sludge, are commonly used as a fertilizer and amendment to improve soil productivity. Application of biosolids to meet the nitrogen (N) requirements of crops can lead to accumulation of phosphorus (P) in soils, which may result in P loss to water bodies. Since 1996, biosolids have been applied to a Pinus radiata D. Don plantation near Nelson City, New Zealand, in an N-deficient sandy soil. To investigate sustainability of the biosolids application programme, a long-term research trial was established in 1997, and biosolids were applied every three years, at three application rates, including control (no biosolids), standard and high treatments, based on total N loading. The objective of this study was to evaluate the effect of repeated application of biosolids on P mobility in the sandy soil.
Soil samples were collected in August 2004 from the trial site at depths of 0-10, 10-25, 25-50, 50-75, and 75-100 cm. The soil samples were analysed for total P (TP), plant-available P (Olsen P and Mehlich 3 P), and various P fractions (water-soluble, bioavailable, Fe and Al-bound, Ca-bound, and residual) using a sequential P fractionation procedure.
Soil TP and Olsen P in the high biosolids treatment (equivalent to 600 kg N ha(-1) applied every three years) had increased significantly (P<0.05) in both 0-10 cm and 10-25 cm layers. Mehlich 3 P in soil of the high treatment had increased significantly only at 0-10 cm. Olsen P appeared to be more sensitive than Mehlich 3 P as an indicator of P movement in a soil profile. Phosphorus fractionation revealed that inorganic P (Al/Fe-bound P and Ca-bound P) and residual P were the main P pools in soil, whereas water-soluble P accounted for approximately 70% of TP in biosolids. Little organic P was found in either the soil or biosolids. Concentrations of water-soluble P, bioavailable inorganic P (NaHCO3 Pi) and potentially bioavailable inorganic P (NaOH Pi) in both 0-10 and 10-25 cm depths were significantly higher in the high biosolids treatment than in the control. Mass balance calculation indicated that most P applied with biosolids was retained by the top soil (0-25 cm). The standard biosolids treatment (equivalent to 300 kg N ha(-1) applied every three years) had no significant effect on concentrations of TP, Mehlich 3 P and Olsen P, and P fractions in soil.
The results indicate that the soil had the capacity to retain most biosolids-derived P, and there was a minimal risk of P losses via leaching in the medium term in the sandy forest soil because of the repeated biosolids application, particularly at the standard rate.
Application to low-fertility forest land can be used as an environmentally friendly option for biosolids management. When biosolids are applied at a rate to meet the N requirement of the tree crop, it can take a very long time before the forest soil is saturated with P. However, when a biosolids product contains high concentrations of P and is applied at a high rate, the forest ecosystem may not have the capacity to retain all P applied with biosolids in the long term.
目标、范围与背景:生物固体废弃物,即经过处理的污水污泥,通常用作肥料和土壤改良剂以提高土壤生产力。施用生物固体废弃物来满足作物的氮(N)需求可能会导致土壤中磷(P)的积累,进而可能导致磷流失到水体中。自1996年以来,生物固体废弃物已被施用于新西兰尼尔森市附近一片缺氮砂质土壤上的辐射松人工林。为了研究生物固体废弃物施用计划的可持续性,1997年开展了一项长期研究试验,基于总氮负荷,每三年以三种施用量(包括对照(不施生物固体废弃物)、标准处理和高量处理)施用生物固体废弃物。本研究的目的是评估重复施用生物固体废弃物对砂质土壤中磷迁移性的影响。
2004年8月从试验场地0 - 10、10 - 25、25 - 50、50 - 75和75 - 100厘米深度采集土壤样本。使用连续磷分级程序分析土壤样本中的总磷(TP)、植物有效磷(Olsen磷和Mehlich 3磷)以及各种磷组分(水溶性、生物可利用性、铁和铝结合态、钙结合态和残余态)。
高量生物固体废弃物处理(相当于每三年施用600千克氮公顷⁻¹)的0 - 10厘米和10 - 25厘米土层中的土壤TP和Olsen磷显著增加(P < 0.05)。高量处理土壤中的Mehlich 3磷仅在0 - 10厘米处显著增加。作为土壤剖面中磷迁移指标,Olsen磷似乎比Mehlich 3磷更敏感。磷分级显示无机磷(铁/铝结合态磷和钙结合态磷)和残余磷是土壤中的主要磷库,而水溶性磷约占生物固体废弃物中TP的70%。在土壤和生物固体废弃物中均未发现少量有机磷。高量生物固体废弃物处理的0 - 10厘米和10 - 25厘米深度的水溶性磷、生物可利用无机磷(NaHCO₃磷)和潜在生物可利用无机磷(NaOH磷)浓度均显著高于对照。质量平衡计算表明,与生物固体废弃物一起施用的大部分磷被表层土壤(0 - 25厘米)保留。标准生物固体废弃物处理(相当于每三年施用300千克氮公顷⁻¹)对土壤中TP、Mehlich 3磷和Olsen磷浓度以及磷组分没有显著影响。
结果表明土壤有能力保留大部分源自生物固体废弃物的磷,并且由于重复施用生物固体废弃物,特别是标准施用量,在中期砂质森林土壤中通过淋溶造成磷流失的风险极小。
应用于低肥力林地可作为生物固体废弃物管理的一种环境友好选择。当以满足林木作物氮需求的速率施用生物固体废弃物时,森林土壤达到磷饱和可能需要很长时间。然而,当一种生物固体废弃物产品含高浓度磷并以高量施用时,从长期来看森林生态系统可能没有能力保留与生物固体废弃物一起施用的所有磷。
