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1、生态环境 2008, 17(5): 1728-1731 http:/Ecology and Environment E-mail: 基金项目:国家高技术研究发展计划(863)项目(2003AA601070);江苏省高校自然科学基础研究项目(07KJD610196)作者简介:李大鹏(1975 年生),男,讲师,博士研究生,城市水环境修复理论研究。E-mail: *通讯联系人, E-mail: 收稿日期:2008-04-04 静态条件下底泥中不同形态磷的变化规律李大鹏 1, 2,黄勇 2*,李伟光 11. 哈尔滨工业大学市政环境学院,黑龙江 哈尔滨 150090;2. 苏州科技学院环境科学与工程系
2、,江 苏 苏州 215011摘要:上覆水中磷被结合到底泥中时,不同形态磷的数量将会改变,由此导致磷的释放能力和生物有效性被显著改变。以富营养化河道上覆水和底泥为材料,考察了静态条件下,底泥中不同形 态 磷的变化规律及其对磷的生物有效性的影响。结果表明,潜在活性磷(PMP)含量显著增加, NH4Cl-P、BD-P、NaOH-nrP 分别增加了 297.68%、10.73%、30.49%。难释放态磷则基本保持不变。潜在活性磷 对生物有效磷的形成具有 显著的影响, 4 种生物有效磷中的 3 种(WSP 、Olsen-P、AAP)均与其在 Olsen-P WSPRDP。其中,AAP 在 TP 中所占比
3、例最大,并显著高于其它生物有效磷, 说明 AAP 更适合于描述底泥中磷的生物有效性。随着时间的迁移,AAP 占 TP 的百分比 显著增加。与初始状态相比,第 30 天,AAP/TP 增加了 5.79%。并且,AAP 的变化与潜在活性磷的变化是同步的。由此可 见,静 态条件下,上覆水中磷向底泥迁移时,以形成潜在活性磷和生物有效磷为主。将不同反应时间的 4 种不同 BAP 与潜在活性磷建立线性回归方程(图 5)。结 果表明,除 RDP 外,WSP、Olsen-P、AAP 均与 PMP 在 0.01 水平上显著正相关。PMP 对 AAP 的形成的影响明显大于其它 3 种 BAP,并且注意到,底泥中的
4、 PMP 含量越高,则 AAP 形成量就越大。由此说明,静 态条件下,不同形态磷的变化对生物有效磷的形成有着显著的影响。3 结论静态条件下,上覆水中磷被结 合到底泥中时,底泥中形态磷的变化以潜在活性磷为主, 难释放态磷基本保持不变。潜在活性磷 对生物有效磷的形成具有显著的影响,4 种 BAP 中的 3 种(WSP, Olsen-P, AAP)均与潜在活性磷在 0.01 水平上显著正相关,并且潜在活性磷对 AAP 的形成影响最为显著。参考文献:1 VAN DER MOLEN D T, PORTIELJE R, BOERS P C M, et al. Changes in sediment pho
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9、001502002503000 1 3 10 20 30t/dw(P)/(mgkg-1)WSP RDP Olsen-P AAP图 4 生物有效磷的变化规律Fig. 4 Variation of bioavailable phosphorus in sediments050100150200250300700 750 800 850 900 950 1000w(PMP)/(mgkg-1)w(BAP)/(mgkg-1)WSP RDP Olsen-P AAP图 5 BAP 与 PMP 的相关关系Fig. 5 Correlation of BAP and PMP in the sediments李大鹏
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