参考文献

［1］　Xi B， Zhao X， He X， Huang C， Tan W， Gao R， et al. Successions and diversity of humic-reducing microorganisms and their association with physical-chemical parameters during composting. Bioresource Technology， 2016，219：204-211.

［2］　刘强， 陈玲， 邱家洲， 赵建夫. 污泥堆肥对园林植物生长及重金属积累的影响. 同济大学学报（自然科学版）， 2010，38：870-875.

［3］　Gannes V D， Eudoxie G， Hickey W J. Prokaryotic successions and diversity in composts as revealed by 454-pyrosequencing. Bioresource Technology， 2013，133：573.

［4］　Rivas R， Vel􀅡zquez E， Willems A， Vizcaíno N， Subbarao N S， Mateos P F， et al. A New Species of Devosia That Forms a Unique Nitrogen-Fixing Root-Nodule Symbiosis with the Aquatic Legume Neptunia natans （L.f.） Druce. Applied & Environmental Microbiology， 2002，68：5217-5222.

［5］　Rau J， Hansjoachim Knackmuss A， Stolz A. Effects of Different Quinoid Redox Mediators on the Anaerobic Reduction of Azo Dyes by Bacteria. Environmental Science & Technology， 2002，36：1497-1504.

［6］　Wang Y， Wu C， Wang X， Zhou S. The role of humic substances in the anaerobic reductive dechlorination of 2，4-dichlorophenoxyacetic acid by Comamonas koreensis strain CY01. Journal of Hazardous Materials， 2009，：164：941-947.

［7］　Ka J O， Holben W E， Tiedje J M. Genetic and phenotypic diversity of 2，4-dichlorophenoxyacetic acid （2，4-D）-degrading bacteria isolated from 2，4-D-treated field soils. Applied & Environmental Microbiology， 1994，60：1106-1115.

［8］　Wu C， Zhuang L， Zhou S， Yuan Y， Yuan T， Li F. Humic substance-mediated reduction of iron（Ⅲ） oxides and degradation of 2，4-D by an alkaliphilic bacterium， Corynebacterium humireducens MFC-5. Microbial Biotechnology， 2013，6：141-149.

［9］　Wu J， Zhao Y， Zhao W， Yang T， Zhang X， Xie X， et al. Effect of precursors combined with bacteria communities on the formation of humic substances during different materials composting. Bioresource Technology， 2017，226：191.

［10］　Piepenbrock A， Kappler A. Humic substances and extracellular electron transfer. ［DOI］10.1007/978-3-642-32867-1.5，2013.

［11］　Chen Y， Zhou W， Li Y， Zhang J， Zeng G， Huang A， et al. Nitrite reductase genes as functional markers to investigate diversity of denitrifying bacteria during agricultural waste composting. Applied Microbiology & Biotechnology， 2014，98：4233-4243.

［12］　Lovley D R， Woodward J C. Mechanisms for chelator stimulation of microbial Fe（Ⅲ）-oxide reduction. Chemical Geology， 1996，132：19-24.

［13］　Martinez C M， Alvarez L H， Celis L B， Cervantes F J. Humus-reducing microorganisms and their valuable contribution in environmental processes. Applied Microbiology & Biotechnology， 2013，97：10293-10308.

［14］　Tang J， Maie N， Tada Y， Katayama A. Characterization of the maturing process of cattle manure compost. Process Biochemistry， 2006，41：380-389.

［15］　Roelcke M， Han Y， Cai Z， Richter J. Nitrogen mineralization in paddy soils of the Chinese Taihu Region under aerobic conditions. Nutrient Cycling in Agroecosystems， 2002，63：255-266.

［16］　Zhang J， Zeng G， Chen Y， Yu M， Yu Z， Li H， et al. Effects of physico-chemical parameters on the bacterial and fungal communities during agricultural waste composting. Bioresource Technology， 2011，102：2950.