不同溶氧条件大薸腐解过程的水质效应

doi:10.3969/j.issn.1000-2006.201609062

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南京林业大学学报（自然科学版） ›› 2017, Vol. 41 ›› Issue (06): 127-133.doi: 10.3969/j.issn.1000-2006.201609062

不同溶氧条件大薸腐解过程的水质效应

喜文娟,刘京,王薇,牛宇琛,徐驰,刘茂松

南京大学生命科学学院,江苏南京 210093

出版日期:2017-12-18 发布日期:2017-12-18
基金资助:
基金项目:国家水体污染控制与治理科技重大专项(2012zx07101013); 国家自然科学基金项目(41271197,51309242) 第一作者:喜文娟(xwj1772464@163.com)。*通信作者:刘茂松(msliu@nju.edu.cn),副教授。

Effects of decomposition of Pistia stratiotes on water quality under different dissolvedoxygen conditions

XI Wenjuan, LIU Jing, WANG Wei, NIU Yuchen, XU Chi, LIU Maosong

School of Life Sciences, Nanjing University, Nanjing 210093, China

Online:2017-12-18 Published:2017-12-18

摘要/Abstract

摘要： 【目的】研究水生植物的分解过程及其水质效应在不同水体溶氧条件下存在的差异,为水体中植物残体管理及水质调控提供参考。【方法】采用塑料箱模拟富营养化水体环境的方法,将大薸放入试验箱分别在非充气(NA)与充气(IA)状态,以及室内弱光条件下,测定不同时间水体的水质指标,分析大薸腐解过程中主要水质指标的变化。【结果】高溶氧条件下植物体分解较快,水质指标的阶段性变化具同步性,实验初期(1～25 d)主要水质指标变化较大,实验中后期(26～95 d)主要水质指标相对稳定。实验初期,IA组NO^-₃-N、NO^-₂-N浓度显著高于NA组,PO^3-₄-P浓度显著低于NA组; 实验中后期,除NH⁺₄-N外,IA组各主要水质指标均低于NA组。不同生物量水平组间,IA各组中主要水质指标达到浓度最大值的时间基本一致; NA各组中NO^-₃-N、NO^-₂-N、PO^3-₄-P浓度达到最大值的时间随初始植物生物量的增加而延迟,但NO^-₃-N、NO^-₂-N浓度最大值组间差异较小,仅PO^3-₄-P浓度最大值随初始植物生物量增加而增加。【结论】相对于植物生物量对植物分解过程水质效应的影响,溶氧浓度对水质的影响更大。高溶氧条件下,主要水质指标优于低溶氧条件,特别是实验初期,组间主要水质指标差异较大,实验中后期溶氧条件对水质指标的影响则相对较小。

Abstract: 【Objective】Understanding the differences in the decomposition of aquatic plants and water quality under different dissolved-oxygen levels plays an important role in plant residue management and water-quality control. 【Method】A eutrophic aquatic environment was simulated using a plastic box with Pistia stratiotes under conditions of non-inflated aeration(NA)and inflated aeration(IA).Under indoor and low-light conditions, water-quality indices were determined at different time points. Changes in the major water-quality indices during the decomposition of Pistia stratiotes were analyzed.【Result】Plant residue decomposed faster in the IA group than the NA group; however, the water-quality indices changed synchronously. The major water-quality indices in the initial decomposition stage(1-25 d)changed considerably, and was relatively stable in the subsequent stages(26-95 d).In the initial stage, the concentrations of NO^-₃-N and NO^-₂-N remained significantly higher in the IA group than the NA group, and the concentration of PO^3-₄-P remained lower in the IA group than the NA group; in the subsequent stages,in addition to NH⁺₄-N, values of the major indices were lower in the IA group than the NA group. In the IA group,the major water-quality indices reached maximum values simultaneously among different biomass levels. In the NA group, there was a delay in attaining maximum concentrations of NO^-₃-N, NO^-₂-N, and PO^3-₄-P,and the period of delay increased as the initial amount of plant biomass increased, particularly observable in variation in PO^3-₄-P concentration.【Conclusion】Generally, comparing with the effect of plant biomass, inflated aeration had a greater impact on water quality. Under the IA condition, the values of the major water-quality indices were higher than those in the NA group. There were significant differences in water quality between the two groups,especially at the initial stage of the study; however,at subsequent stages,the influence of inflated aeration on water quality indices was relatively small.

中图分类号:

X524

喜文娟,刘京,王薇,等. 不同溶氧条件大薸腐解过程的水质效应[J]. 南京林业大学学报（自然科学版）, 2017, 41(06): 127-133.

XI Wenjuan, LIU Jing, WANG Wei, NIU Yuchen, XU Chi, LIU Maosong. Effects of decomposition of Pistia stratiotes on water quality under different dissolvedoxygen conditions[J].Journal of Nanjing Forestry University (Natural Science Edition), 2017, 41(06): 127-133.DOI: 10.3969/j.issn.1000-2006.201609062.

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不同溶氧条件大薸腐解过程的水质效应

Effects of decomposition of Pistia stratiotes on water quality under different dissolvedoxygen conditions

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