帮助 关于我们

返回检索结果

水溶性有机物电子转移能力及其生态效应
Electron transfer capacities of dissolved organic matter and its ecological effects

查看参考文献52篇

毕冉 1   周顺桂 2   袁田 2   庄莉 2   袁勇 2 *  
文摘 水溶性有机物(Dissolved organic matter,DOM)是生态系统最为活跃的有机物组分,参与众多物理、化学及生物过程。DOM具有电子转移能力,主要原因在于结构中包含的醌基官能团,通过醌、半醌和氢醌之间的可逆转化完成电子转移过程。DOM作为电子穿梭体,循环参与电子转移的能力是其发挥生态效应的重要体现。研究表明,DOM可以通过氧化还原反应介导环境中Cr(遇)、Hg(域)等重金属及卤代烃、硝基芳香化合物等持久性有机污染物降解转化。综述了DOM电子转移能力机理、途径及可循环性,电子转移能力测定方法,以及DOM电子转移能力的生态效应并展望研究方向。
其他语种文摘 Dissolved organic matter (DOM) represents one of the most mobile and reactive organic matter fractions, controlling a number of physical, chemical and biological processes in ecosystem. Both laboratory and field studies show that litter and humus are the most important source of DOM in soils. Due to the complex molecules structure, a general chemical definition of DOM is impossible. DOM is often defined operationally as a continuum of organic molecules of different sizes, structures and functional properties that is able to pass through a filter with a pore size of 0. 45 μm. DOM consists of low molecular weight substances, such as organic acids and amino acids, as well as complex molecules of high molecular weight, such as humic substances and enzymes. Earlier researchers primarily focused on the complexation and adsorption properties of DOM with heavy metals and organic pollutants, by which their behaviors in soils, such as the adsorption, desorption, and transportation, were greatly affected. Recently, discoveries on the redox reactivity of humus have illuminated a new thought that DOM may also have the same mechanisms. With the aid of numerous analytical techniques, there were multiple lines of evidence for the redox reactivity of DOM. Quinine groups have main contribution to the electron transfer of DOM. Quinones are a versatile class of biomolecules found in numerous substances such as living cells, extracellular material and so forth. Quinones can be cycled among three redox states: oxidized, semiquinone radical, and reduced, thus, the electron transfer processes reversibly take place with the transformation among benzoquinone, semiquinone and hydroquinone. The benzoquinone of DOM can undergo either one-electron reduction to the semiquinone or two-electron reduction to the hydroquinone. DOM can accept electrons from other species when electron donors, especially the humic-reducing bacteria, are available in the environment. Alternatively, the reduced DOM could be oxidized by those substances with high redox potentials, such as oxygen. Previous studies showed that the electron transfer capacity of DOM was closely related to the degradation of heavy metals (e. g. Cr (VI) and Hg(II)) and persistent organic pollutants (e. g. halohydrocarbon and nitroaromatic) in the environments. DOM can function as electron shuttle for continuous electron transfer between the reduced electron donor and the oxidized priority pollutants, displaying a significant effect on the fate and transport of organic and inorganic environmental pollutants. The redox properties of DOM, including electron transfer reversibility, electron acceptor capacity (EAC) and electron donor capacity (EDC), have been provided by chemical and biochemical methods. Nevertheless, the traditional methods (Zn and Fe~(3+) assays) are normally time consuming and usually require high degree of skill and experience to achieve reproducible results. Lately, a novel and rapid electrochemical approach has been presented to investigate the redox properties of DOM, which overcomes the limitations of the methods previously used. Though the researches on DOM are intensive, our knowledge of the formation and function of DOM is still fragmented and often inconsistent. Thus, a systematic review is benefit to comprehensive understanding of the ecological effects of DOM. The purpose of this paper was to review three main aspects: (1) the mechanism, pathway and capability of electron transfer for DOM; (2) the methods for measuring electron transfer capacity; (3) the ecological effects and research prospects of DOM in the future.
来源 生态学报 ,2013,33(1):45-52 【核心库】
DOI 10.5846/stxb201111071685
关键词 水溶性有机物 ; 电子转移能力 ; 测定方法 ; 生态效应
地址

1. 中国科学院广州地球化学研究所, 广州, 510640  

2. 广东省生态环境与土壤研究所, 广州, 510650

语种 中文
文献类型 综述型
ISSN 1000-0933
学科 环境科学基础理论
基金 国家自然科学基金
文献收藏号 CSCD:4737880

参考文献 共 52 共3页

1.  王艮梅. 陆地生态系统中水溶性有机物动态及其环境学意义. 应用生态学报,2003,14(11):2019-2025 CSCD被引 44    
2.  Dunnivant F M. Reduction of substituted nitrobenzenes in aqueous solutions containing natural organic matter. Environmental Science and Technology,1992,26(11):2133-2141 CSCD被引 25    
3.  黄泽春. 陆地生态系统中水溶性有机质的环境效应. 生态学报,2002,22(2):259-269 CSCD被引 74    
4.  付美云. 垃圾渗滤液水溶性有机物对土壤Pb溶出的影响. 环境科学,2007,28(2):243-248 CSCD被引 15    
5.  Kappler A. Natural organic matter as reductant for chlorinated aliphatic pollutants. Environmental Science and Technology,2003,37(12):2714-2719 CSCD被引 28    
6.  Lovley D R. Humic substances as electron acceptors for microbial respiration. Nature,1996,382(6590):445-448 CSCD被引 161    
7.  Cory R M. Fluorescence spectroscopy reveals ubiquitous presence of oxidized and reduced quinones in dissolved organic matter. Environmental Science and Technology,2005,39(21):8142-8149 CSCD被引 193    
8.  Bauer M. Electron transfer capacities and reaction kinetics of peat dissolved organic matter. Environmental Science and Technology,2007,41(1):139-145 CSCD被引 17    
9.  Shcherbina N S. Redox and complexation interactions of neptunium (V) with quinonoid-enriched humic derivatives. Environmental Science and Technology,2007,41(20):7010-7015 CSCD被引 2    
10.  Perminova I V. Design of quinonoid-enriched humic materials with enhanced redox properties. Environmental Science and Technology,2005,39(21):8518-8524 CSCD被引 7    
11.  Minderlein S. Humic-rich peat extracts inhibit sulfate reduction, methanogenesis, and anaerobic respiration but not acetogenesis in peat soils of a temperate bog. Soil Biology and Biochemistry,2010,42(12):2078-2086 CSCD被引 6    
12.  Heitmann T. Electron transfer of dissolved organic matter and its potential significance for anaerobic respiration in a northern bog. Global Change Biology,2007,13(8):1771-1785 CSCD被引 10    
13.  许伟. 水溶性有机物的电子穿梭功能研究. 环境科学,2009,30(8):2297-2301 CSCD被引 4    
14.  Huang D Y. Comparison of dissolved organic matter from sewage sludge and sludge compost as electron shuttles for enhancing Fe(Ⅲ) bioreduction. Journal of Soils and Sediments,2010,10(4):722-729 CSCD被引 7    
15.  Scott D T. Quinone moieties act as electron acceptors in the reduction of humic substances by humics-reducing microorganisms. Environmental Science and Technology,1998,32(19):2984-2989 CSCD被引 81    
16.  Nurmi J T. Electrochemical properties of natural organic matter (NOM), fractions of NOM, and model biogeochemical electron shuttles. Environmental Science and Technology,2002,36(4):617-624 CSCD被引 16    
17.  Struyk Z. Redox properties of standard humic acids. Geoderma,2001,102(3/4):329-346 CSCD被引 31    
18.  Ratasuk N. Characterization and quantification of reversible redox sites in humic substances. Environmental Science and Technology,2007,41(22):7844-7850 CSCD被引 32    
19.  Maurer F. Reduction and reoxidation of humic acid: influence on spectroscopic properties and proton binding. Environmental Science and Technology,2010,44(15):5787-5792 CSCD被引 5    
20.  Yuan T. A rapid and simple electrochemical method for evaluating the electron transfer capacities of dissolved organic matter. Journal of Soils and Sediments,2011,11(3):467-473 CSCD被引 12    
引证文献 7

1 朱江鹏 荧光猝灭法研究洛克沙胂与腐殖酸的相互作用 环境科学,2014,35(7):2620-2626
CSCD被引 8

2 赵海超 施肥对不同肥力春玉米田土壤溶解性有机质的影响 生态环境学报,2014,23(8):1286-1291
CSCD被引 8

显示所有7篇文献

论文科学数据集
PlumX Metrics
相关文献

 作者相关
 关键词相关
 参考文献相关

版权所有 ©2008 中国科学院文献情报中心 制作维护:中国科学院文献情报中心
地址:北京中关村北四环西路33号 邮政编码:100190 联系电话:(010)82627496 E-mail:cscd@mail.las.ac.cn 京ICP备05002861号-4 | 京公网安备11010802043238号