物料预处理对堆肥减量化、腐殖化和稳定化的影响及其微生物机制

堆肥是有机固体废弃物处理与资源化的主要途径之一,包括矿化和腐殖化两个过程,且都和微生物活动有关。矿化过程会产生二氧化碳(CO2)等温室气体,是一个典型的温室气体释放过程。腐殖化过程则会产生稳定的腐殖质,则是优良的土壤改良剂。在堆肥稳定化的前提下,如何有效减少堆肥过程中的CO2释放,强化堆肥的腐殖化过程,增加作为优良土壤改良剂的腐殖质产量,对于发展低碳化堆肥技术,实现堆肥的资源化利用具有重要意义。本文选取水稻秸秆和餐厨垃圾作为堆肥原料,研究不同预处理对堆肥过程中矿化和腐殖化过程的影响,并探讨了不同预处理影响矿化和腐殖化过程的微生物机理。结果表明堆料加热预处理后,堆肥的矿化作用被明显削弱,总碳(TC)减量率仅为23.4%,并且最后形成了可观产量的稳定腐殖质(每kg堆料70 d后腐殖质含量为22.09 g±0.35 g,腐殖化系数达2.0),因此加热预处理后的堆肥过程在保证稳定腐殖质的产量前提下更低碳化。预处理通过影响堆料的性质和初始状态下堆料中微生物的种类和数量从而影响堆肥的矿化和腐殖化过程。活性微生物量与脱氢酶活性是矿化过程的主要决定因素,而多酚氧化酶活性主要影响堆肥的稳定腐殖化过程。     

微生物在有机固废堆肥中的作用与应用

好氧堆肥是实现有机固体废弃物资源化利用的主流处理方式。堆肥腐熟是一个由微生物主导的生理生化过程,堆料通过微生物发酵实现矿质化、腐殖化和无害化,转变成腐熟的有机肥。传统的好氧堆肥存在发酵周期长、养分损失、恶臭及温室气体排放等不足。在堆肥过程中添加微生物是弥补传统好氧堆肥缺陷、提高堆肥品质和功效的有效方法。近年来,国内外在好氧堆肥过程中主要微生物类群与其演替规律、外源添加微生物的作用与功能等方面取得了较大进展。本文简述好氧堆肥基本过程与主要影响因素,以及这个过程中主要微生物类群与其演替规律,重点介绍有关微生物添加剂在好氧堆肥中的应用及其作用方面的研究进展。同时,我们对目前微生物添加剂在应用中存在的问题进行分析并对解决途径进行探讨。     

堆肥中木质素降解微生物对腐殖质形成的作用

堆肥化是处理有机固体废物的主要方法之一。但传统堆肥法存在历时长、肥效低等问题 ,因此加速腐殖化进程可提高堆肥效率和堆肥质量。综述了堆肥中降解木质素的微生物种类的腐殖质的组成 ,介绍了木质素降解与腐殖质形成的关系 ,最后阐述了堆肥中各木质素降解微生物对腐殖质形成的作用。     

两种微生物菌剂对西番莲果渣高温堆肥腐熟进程的影响

研究了在西番莲果渣堆肥体系中加入两种微生物菌剂（福贝和榕风）后的温度、C／N、NH4^＋ -N和NO3^- -N的动态变化及对西番莲果渣堆肥产品品质的影响．结果表明,在西番莲果渣中加入微生物菌剂能增加高温分解持续时间,加快物料C／N降低的速率,促进NH4^＋ -N向NO3^- -N转化,加快西番莲果渣堆肥腐熟化进程．添加福贝和榕风菌剂后,堆肥高温持续时间分别比对照（4d）增加7d和8d;腐熟后堆肥的NO3^- -N浓度分别比对照增加58．0％和64．2％．添加菌种显著增加了西番莲果渣堆肥的N、P、K养分含量,降低了堆肥容重,提高了堆肥总孔隙度和持水孔隙度,改善了堆肥产品的品质．两种菌剂间对西番莲果渣高温腐熟进程的影响没有显著差异,但福贝菌剂更有利于改善堆肥品质．     

城市生活垃圾堆肥发酵中微生物菌群变化规律的研究

通过对垃圾处理厂静态堆肥不同区域的微生物菌群与数量的分析,表明了城市生活垃圾堆肥发酵中微生物菌群的变化规律,温度与微生物菌群的相关性,指出了高温微生物菌群数量影响堆肥的效率。建议在静态一次堆肥发酵周期中,增加通气量和翻堆频率,有利于增强微生物菌群的活力和提高堆肥质量。     

湿度对堆肥理化性质的影响

水分是堆肥微生物生命活动的基础 ,也是堆肥中重要的工艺控制参数。弄清湿度对堆肥微生物及理化性质的影响 ,对于优化堆肥工艺参数、提高堆肥效率、降低投资和运行成本具有重要意义。综述了堆肥湿度研究的动态 ,指出了当前研究中存在的问题 ,并提出了未来的研究方向。大量的研究表明 ,湿度低于 4 5 %或高于 6 5 %都不利于堆肥处理。湿度太高会导致堆料的压实度增加、FAS减少、透气性能降低 ,从而导致堆体内氧气供应不足、堆肥升温困难、有机物降解速率降低、堆肥周期延长。湿度过低 ,水分会限制堆肥微生物的新陈代谢 ,导致微生物活性下降、堆肥腐熟困难。由于鼓风、散热、水蒸发等会使堆体内存在湿度的空间变异 ,也会降低堆肥效率和堆肥产品的质量。另外 ,堆肥湿度还影响堆肥的保肥能力。由各文献得出结论 ,堆肥的最佳湿度范围一般为 5 0 %～ 6 0 %左右     

有机物料种类及腐熟水平对土壤微生物群落的影响

应用Biolog方法研究了温室盆栽番茄条件下,施用不同种类及不同腐熟水平的有机物料对土壤微生物群落的影响,施用有机物料60d后取土分析土壤微生物群落多样性及土壤微生物对Biolog微平板中胺、氨基酸、糖、羧酸、聚合物和其它类碳源的利用情况,结果表明,施用有机物料可提高土壤微生物群落多样性,施用新鲜酒糟的多样性指数略高于施用腐熟10d酒糟,牛粪不同腐熟水平对多样性影响显著,且对多样性具有正向或负向的影响;对照和施用酒糟的土壤微生物对聚合物的利用率高于施用牛粪处理,施用新鲜物料处理的土壤微生物对聚合物的利用率高于施用腐熟物料处理。     

超高温堆肥促进氮素减损的微生物机制研究进展

堆肥中氮的循环在很大程度上依赖微生物驱动的氮素转化。传统高温堆肥最高堆温普遍在55-60℃,温度的提高有利于缩短堆肥周期和提高堆肥品质。超高温堆肥作为近年来快速发展的新兴技术,不但能突破传统堆肥工艺堆温低的局限,并且持续的超高温调控了堆肥微生物组、堆肥环境与氮素的互作,减少了氮素的损失。本文综述了堆体的氮循环过程及超高温堆肥技术在保氮方面的显著优势,以及超高温堆肥过程中具有氮代谢功能的优势微生物种群及其影响因素,重点介绍有关超高温堆肥控制氮素损失的作用机制研究进展,同时对超高温堆肥现有研究中存在的问题进行分析并探讨解决途径。     

有机固体废弃物堆肥的物质变化及腐熟度评价

堆肥是资源化处理有机固体废弃物的有效途径之一．有机固体废弃物的种类繁多,物科的性质差异很大,另外,由于堆肥条件的不同,也会引起堆肥的物质变化有很大差异．堆肥的稳定度和腐熟度是衡量堆肥产品质量的尺度,其评价对于安全农用有着重要意义．稳定度则重于堆肥施用对周围环境的影响,而腐熟度则重于堆肥施用对植物生长的影响,它们受堆肥物料,堆肥条件等诸多因素的综合影响,其评价指标因而多种多样．堆肥稳定度主要从堆肥的温度、颜色、CO2是最为简便的稳定度评价指标,当其趋于环境温度时,表明堆肥达到稳定．堆肥腐熟度的评价指标很多,包括化学指标、生物活性指标以及植物毒性指标3类,其中种子发芽系数作为植物毒性指标被认为是最可靠的评价指标之一。     

堆肥处理对污泥腐殖物质形态及其重金属分配的影响

采用透析、凝胶色谱 (SephadexG 75 )研究了污泥堆肥前后腐殖质分子大小的变化及重金属Cu和Zn在各级组分中的分配。透析结果表明 ,污泥经过堆腐以后 ,腐殖质中小分子物质 (<10 0 0Da)组分的含量下降 6 4 % ,而相对高分子组分 (>2 5 0 0 0Da)却增加了 6 8%。凝胶色谱进一步证实 ,污泥经过 4 9d堆腐后 ,腐殖质中大于 2 0 0 0KDa的大分子组分是堆肥起始时的2 3倍。而小分子组分明显减少 ,表现在小分子组分的凝胶洗脱体积明显减少。堆肥腐熟以后 ,腐殖质吸附的Cu、Zn元素含量增加 ,其中Cu主要被吸附在大分子物质上 ,而Zn主要与小分子物质结合     

Microbiological parameters as indicators of compost maturity

AIMS: The objectives of this study were to determine the changes of microbial properties of pig manure collected from pens with different management strategies and composted using different turning and moisture regimes; relate their association with humification parameters and compost temperature; and identify the most suitable microbial indicators of compost maturity. METHODS AND RESULTS: Six different microbial parameters, including total bacterial count, oxygen consumption rate, ATP content, dehydrogenase activity, and microbial biomass C and N, along with humification parameters [humic acid (HA), fulvic acid (FA) and HA : FA ratio] and compost temperature were monitored during composting. Significant positive correlations were found between temperature and microbial properties, including O2 consumption rate, ATP content, dehydrogenase activity, and microbial biomass N. The humification parameters also showed significant correlations with microbial properties of the manure compost. For instance, HA contents of pig manures was positively correlated with total aerobic heterotrophs, and microbial biomass N and C; and negatively correlated with O2 consumption rate, ATP content, and dehydrogenase activity. Among the six microbial parameters examined, dehydrogenase activity was the most important factor affecting compost temperature and humification parameters. Composting strategies employed in this study affected the speed of composting and time of maturation. If the moisture content is maintained weekly at 60% with a 4-day turning frequency, the pig manure will reach maturity in 56 days. CONCLUSIONS: The composting process went through predictable changes in temperature, microbial properties and chemical components despite differences in the initial pig manure and composting strategies used. Among the six microbial parameters used, dehydrogenase activity is the most suitable indicator of compost maturity. Compared with respiration rate, ATP content and microbial biomass procedures, dehydrogenase activity is the simplest, quickest, and cheapest method that can be used to monitor the stability and maturity of composts. SIGNIFICANCE AND IMPACT OF THE STUDY: The results presented here show that microbial parameters can be used in revealing differences between composts and compost maturity. The statistical relationship established between humification parameters and microbial parameters, particularly dehydrogenase activity, demonstrates that it is possible to monitor the composting process more easily and rapidly by avoiding longer and more expensive analytical procedures.     

Purification and Characterization of Laccase from Chaetomium thermophilium and Its Role in Humification

Chaetomium thermophilium was isolated from composting municipal solid waste during the thermophilic stage of the process. C. thermophilium, a cellulolytic fungus, exhibited laccase activity when it was grown at 45°C both in solid media and in liquid media. Laccase activity reached a peak after 24 h in liquid shake culture. Laccase was purified by ultrafiltration, anion-exchange chromatography, and affinity chromatography. The purified enzyme was identified as a glycoprotein with a molecular mass of 77 kDa and an isoelectric point of 5.1. The laccase was stable for 1 h at 70°C and had half-lives of 24 and 12 h at 40 and 50°C, respectively. The enzyme was stable at pH 5 to 10, and the optimum pH for enzyme activity was 6. The purified laccase efficiently catalyzed a wide range of phenolic substrates but not tyrosine. The highest levels of affinity were the levels of affinity to syringaldazine and hydroxyquinone. The UV-visible light spectrum of the purified laccase had a peak at 604 nm (i.e., Cu type I), and the activity was strongly inhibited by Cu-chelating agents. When the hydrophobic acid fraction (the humic fraction of the water-soluble organic matter obtained from municipal solid waste compost) was added to a reaction assay mixture containing laccase and guaiacol, polymerization took place and a soluble polymer was formed. C. thermophilium laccase, which is produced during the thermophilic stage of composting, can remain active for a long period of time at high temperatures and alkaline pH values, and we suggest that this enzyme is involved in the humification process during composting.     

Co-composting of soybean residues and leaves in Hong Kong

The goal of this project was to evaluate the feasibility of co-composting of soybean residues and leaves and the effects of turning frequency on compost quality. Soybean residues were mixed with leaves and sawdust in 1:1:3 (w/w wet weight) for achieving a C/N ratio of about 30. Three heaps of about 4 m3 of compost mixtures were prepared receiving a turning frequency of daily (pile A), 3-day (pile B) and weekly (pile C) turning. Different turning frequencies did not significantly affect the changes in pH and volatile solids throughout the composting period. High turning frequency caused a lower electrical conductivity and NH4-N contents as well as a shorter duration of thermophilic phase, because of a high heat loss by evaporation and volatilization of ammonia in the pile. The highest C decomposition of 4% occurred in the pile with a 3-day turning period, which coincided with the higher-nitrogen content in this treatment. All treatments with different turning frequencies reached maturation at 63 days as indicated by the soluble organic carbon, soluble NH4-N, C/N ratio and cress seed germination index. However, increasing the aeration during composting period was beneficial in accelerating the maturation process. Taking into consideration less labour and lower operation costs as compared to daily turning, it can be suggested that a 3-day turning frequency would be more appropriate for reaching acceptable quality of compost and ease in operation.     

Emission of methane and carbon dioxide and earthworm survival during composting of pharmaceutical sludge and spent mycelia

Emissions of methane (CH4) and carbon dioxide (CO2) from spent mycelia of the mold Penicilium notatum and sludge from the effluent treatment facility (ETPS) of a pharmaceutical industry were estimated twice during a two-week composting before vermicomposting. These wastes are dumped in landfills or sometimes used in agricultural fields and no reports are available on their greenhouse gas producing potentials. The solid wastes contained appreciable organic carbon and nitrogen while very high Fe, Mn and Zn were found in ETPS only. Pure wastes did not support germination of Vigna radiata L. while mixing soil with ETPS and spent mycelia at the ratios of 12:1 and 14:1 led to 80% and 50% germination, respectively. The wastes were mixed with cowdung at the ratios of 1:1, 1:3 and 3:1 for composting. Carbon dioxide emissions were always significantly higher than CH4 emissions from all the treatments due to prevalence of aerobic condition during composting. From some treatments, CH4 emissions increased with time, indicating increasing activity of anaerobic bacteria in the waste mixtures. Methane emissions ranged from 21.6 to 231.7 microg m(-2) day(-1) while CO2 emissions were greater than thousand times at 39.8-894.8 mg m(-2) day(-1). The amount of C emitted as CH4-C and CO2-C from ranged from 0.007% to 0.081% of total C composted. Cowdung emitted highest CH4 followed by spent mycelia and ETPS while ETPS emitted more CO2 than spent mycelia but lesser than cowdung. Global warming potential of emitted CH4 was found to be in the range of 10.6-27.7 mg-CO2-equivalent on a 20-year time horizon. The results suggest that pharmaceutical wastes can be an important source of CH4 and CO2 during composting or any other stockpiling under suitable moisture conditions. The waste mixtures were found not suitable for vermicomposting after two weeks composting and earthworms did not survive long in the mixtures.     

The interactions of composting and biochar and their implications for soil amendment and pollution remediation: a review

Compost and biochar, used for the remediation of soil, are seen as attractive waste management options for the increasing volume of organic wastes being produced. This paper reviews the interaction of biochar and composting and its implication for soil amendment and pollution remediation. The interaction of biochar and composting affect each other’s properties. Biochar could change the physico-chemical properties, microorganisms, degradation, humification and gas emission of composting, such as the increase of nutrients, cation exchange capacity (CEC), organic matter and microbial activities. The composting could also change the physico-chemical properties and facial functional groups of biochar, such as the improvement of nutrients, CEC, functional groups and organic matter. These changes would potentially improve the efficiency of the biochar and composting for soil amendment and pollution remediation. Based on the above review, this paper also discusses the future research required in this field.     

Quantitative exposure of root crops to indicator enterobacteria from composted spent broiler litter under sub-tropical environment

The study aimed to quantify and compare the incremental exposure of root crops, at point of harvest, to enteric pathogens from untreated vs. composted spent broiler litter (SBL)/bagasse mix in field-crop application. An exposure assessment based on the Source-Pathway-Receptor approach was developed for bacterial indicator species, total coliforms, faecal coliforms, Escherichia coli and faecal enterococci. Event trees were constructed to model the pathways leading to the partitioning of pathogens present in the SBL blend during composting and after land application. The main barriers are induction of composting, high-rate thermophilic phase, maturation phase, and, decay and dilution of the indicator pathogens in the soil. The computed exposures have been expressed in terms of the arithmetic mean. TC, FC, E. coli and FE levels on root crops were reduced to very remote fractions of 0.01826, 0.00046, 0.000132 and 0.000013 kg(-1), respectively. The degree of by-pass (pi) of the treatment at operational scale showed that less than 1-log reduction has been by-passed during each turning event, revealing the effectiveness of turning for process control. The predicted E. coli counts on root crops at point of harvest provided a basis for estimating the exposure potential by the beta-Poisson model. Probability of exposure was 0.782 for raw SBL mix compared to 1.40x10(-11) with composting. It can be concluded that there is a definite advantage in optimally composting SBL mix before land application. The exposure assessment may essentially require modification and fine tuning as and when further data become available.     

Characterization of organic matter degradation during composting of manure-straw mixtures spiked with tetracyclines

The objective of this study was to investigate humification and mineralization of manure-straw mixtures contaminated by tetracyclines during composting. Hen manure, pig manure and rice straw were used as the raw materials. The manure-straw mixtures were spiked with tetracycline, chlortetracycline, and oxytetracycline at the concentration of 60 mg/kg dry matter. The results show that tetracyclines had no obvious influence on the composting process and more than 93% of the tetracyclines was decreased during a 45-day composting. The Fourier transform infrared (FTIR) spectra indicated that easily biodegradable components such as aliphatic substrates, carbohydrates and polysaccharides were decomposed and the contents of aromatic components relatively rose during the composting. The X-ray diffraction (XRD) spectra confirmed the natural formation of struvite, the degradation of easily biodegradable components, and the mineralization of organic matter during the composting. Therefore, FTIR and XRD analysis can be useful tools for monitoring the composting process.     

烟草废弃物在堆肥领域的研究进展

在烟草生产及加工过程中,通常会产生大量的烟草废弃物,如何有效利用这些废弃物以避免环境污染和资源浪费,已成为烟草行业亟需解决的问解。研究发现,烟草废弃物堆肥化处理是规模化利用废弃资源的有效途径之一,对烟草农业的绿色、低碳、循环、可持续发展具有重要意义。从有机肥堆肥制备技术、肥效研究等方面进行了系统综述,从整体上展示了烟草废弃物堆肥技术的发展现状,以期为国内烟草废弃物源堆肥未来技术的研发及产业化提供一定的参考。通过分析发现,在堆肥制备技术方面,主要有微生物菌剂添加技术、共堆肥技术和烟草材料预处理技术3种,此外还衍生出液态有机肥和厌氧发酵联产有机肥技术;在堆肥肥效研究方面,烟草废弃物堆肥可明显改善土壤的物性参数、化学参数以及生物学参数,显著钝化土壤重金属元素,进而提高作物的产量或品质,其中堆肥与化学肥料配施的效果相对较好;堆肥的多功能化是未来堆肥创新利用的重要途径。