Nature of the action of a compost from olive mill wastewater on Cu sorption by soils

The reaction of two soils that have received composted OMW as manure with Cu solutions is studied. The data were fitted into a multi‐reaction model which considers both reversible and irreversible adsorption sites, and an ‘instantaneous’ fraction. The presence of composted OMW caused a strong increase in the distribution coefficient describing the instantaneous fraction, and the disappearance of the irreversible fraction. This behaviour was attributed to blocking of some sorbing surfaces by the organics, and to new surfaces present in the compost. These effects can have some environmental significance from the viewpoint of Cu mobility.     

猪粪堆肥中一株溶磷菌的筛选鉴定及溶磷能力初步测定

从猪粪堆肥中分离纯化得到一株具有较强溶磷能力的菌株PSM-1,进行了形态学和分子生物学鉴定,研究了其溶磷能力和遗传稳定性.结果表明:通过菌落形态和ITS基因序列分析鉴定,菌株PSM-1为产黄青霉(Penicillium chrysogenum);在3种不同无机磷源液体培养基中其溶磷量依次为Ca3(PO4)2(138.36 mg·L-1)Fe PO4(117.38 mg·L-1)Al PO4(113.76 mg·L-1),且PSM-1的溶磷量均与培养液p H值呈现出显著负相关性;以葡萄糖为碳源、硝酸铵为氮源时,菌株PSM-1的溶磷量最高可达195.67 mg·L-1,比初始有效磷高141.42%;该菌株对碳源和氮源的利用效率分别依次为:葡糖糖蔗糖麦芽糖淀粉,硝酸铵硝酸钾硫酸铵草酸铵;经过20次传代培养后PSM-1的溶磷量保持在(124.54±3.50)mg·L-1,说明其溶磷遗传稳定性良好.研究表明:PSM-1菌株具有良好的溶解无机磷的能力,在土壤微生态改良方面具有重要的应用潜力.     

EM发酵菌在畜禽粪便自然堆肥中的应用研究

畜禽粪便污染是农村主要环境污染,目前农村普遍采用自然堆肥方式处理.本实验模拟自然堆肥方式,加入EM菌微生物菌剂,在高温期进行翻堆通风,通过厌氧和好氧堆肥共同作用,粪便达到腐熟.堆肥过程中跟踪测量堆体温度、并对TOC、TN、TP、TK等技术参数检测,实验结果表明,加入EM菌剂后,发酵周期缩短为自然堆肥腐熟周期的1/3,有效提高高温期最高温度15℃,营养成分没有明显降低.     

城市污泥发酵物对草坪建植和成坪基质完整性的影响研究

文章主要对城市污泥好氧发酵产物用于草坪基质后,对草坪建植指标的影响,包括萌发密度、根重和盖度进行了分析。结果表明施用污泥发酵物对草坪萌发密度和根重无显著影响。盖度指标上,高施用量污泥发酵物表现出显著的提升效应。污泥发酵物的施入对成坪后基质的抗撕裂强度有一定程度降低,但对运输造成的基质完整性并无显著负面影响。     

不同物料堆肥富里酸的结构特征的研究

通过三维荧光平行因子分析（EEM-PARAFAC）和二维相关光谱（2DCOS）分析了富含木质纤维素类物料（果蔬废物和杂草废物）和富含木质素类物料（秸秆废物和园林修剪废物）堆肥形成的富里酸的结构和组成.结果显示，两类堆肥物料形成的富里酸结构差异显著.虽然两类物料的荧光组分含量及变化基本相似，但是特征官能团与其荧光组分的变化顺序却不同.富含木质纤维素类物料堆肥形成的富里酸中类酪氨酸和类色氨酸先于芳环形成，而富含木质素类物料堆肥形成的富里酸中芳环先于类酪氨酸和类色氨酸.并且，研究发现在堆肥高温期和腐熟期，富里酸的芳环含量在木质纤维类和木质类物料中分别增加了约10%和5%，脂肪族的含量分别下降了约10%和6%，说明堆肥过程中富里酸结构中脂肪族逐渐降解并伴随其芳香性逐渐增加；结构方程模型结果表明，类富里酸、脂肪族基团和羧基是富里酸中芳环形成的关键组分.本文研究结果可为明确堆肥过程中富里酸的形成提供理论基础.     

A respirometric method to measure mineralization of polymeric materials in a matured compost environment

A respirometric method was developed to measure the mineralization of polymeric materials in a matured compost environment. For the purpose of evaluating the method, results obtained for the mineralization of glucose and cellulose are presented. The matured compost, in addition to supplied nutrients, micronutrients, and an inoculum, serves as the matrix which supports the microbial activity. Recovery of the substrate carbon in the form of carbon dioxide from the glucose and cellulose added to test vessels was 68 and 70%, respectively. A statistical evaluation of the results obtained on substrate mineralization was carried out and showed acceptable reproducibility between replicate test vessels and test runs. The testing protocol developed has the following important characteristics: (1) the test reactors are maintained at 53 °C at a high solids loading (60% moisture), which has certain characteristics that are similar to a thermophilic compost environment; (2) the test matrix providing microbial activity is derived from readily available organic materials to facilitate reproducibility of the method in different laboratories; (3) the equipment required to perform this test is relatively inexpensive; and (4) the information obtained on polymer mineralization is vital to the study and development of biodegradable polymeric materials.Guest Editor: Dr. Graham Swift, Rohm & Haas.     

Biodegradation of an Epoxy-Based Thermoplastic Polyester, Poly(Hydroxy Ester Ether) in a Laboratory-Scale Compost System

An epoxy-based thermoplastic polyester, poly(hydroxy ester ether), was incubated under aerobic conditions in a laboratory-scale compost system for 168 days to evaluate its potential for biodegradation. Radiolabeled test polymer [uniformly ¹⁴C ring-labeled, poly(hydroxy ester ether)] was incorporated into a mature compost and a sludge-amended compost at a loading of 3 mg test polymer/g compost. ¹⁴C-Cellulose was used as the positive control and a biologically inhibited control reactor was used to assess abiotic degradation of the test polymer. Degradation of the test polymer was assessed by measuring the amount of ¹⁴C-CO₂ from each of the test reactors. In addition, at selected time intervals subsamples of the compost were collected and serially extracted with water, methanol, and dimethylformamide to monitor degradation of the ¹⁴C-test polymer and provide a partial characterization of the degradation intermediates. Extensive degradation of ¹⁴C-poly(hydroxy ester ether) was observed in the test reactors with degradation half-life of the parent polymer (t _1/2) of approximately 32 days. By the end of the study, only 2% of the total ¹⁴C activity in the test reactors was attributed to intact polymer, with most of the measurable ¹⁴C activity converted to either ¹⁴C-CO₂ (26% of total ¹⁴C activity) or nonextractable products (accounting for 60% of the total activity). In contrast to the test reactors, only 3% of the ¹⁴C-poly(hydroxy ester ether) added to the biologically inhibited control reactor was mineralized to ¹⁴C-CO₂. The results obtained from the microbially active and biologically inhibited compost systems indicate that the poly(hydroxy ester ether) polymer was degraded, at least in part, by a biologically mediated process.     

城市生活垃圾堆肥处理工程技术发展探讨

文章分析了我国城市生活垃圾堆肥陷入滞销困境多年的原因，指出摆脱这一困境的技术途径是要大幅度提高堆肥品质。而要实现这一目标，首先必须引进先进的堆肥翻堆技术，缩短腐熟时间，提高腐熟度；其次是应用气流密度分选系统对粗堆肥进行精分选。     

Biodegradation of Whey Protein-Based Edible Films

The biodegradability of the edible films made of whey proteins by disulfide cross-linking was investigated. Whey protein concentrate (WPC) and whey protein isolate (WPI) films were subjected to microbial degradation using Pseudomonas aeruginosa and composting burial degradation. Results from the microbial degradation showed that whey protein films could support the growth of P. aeruginosa. The bacterial growth characteristics were well described using the Gompertz model. WPC films degraded faster than WPI films, suggesting that the biodegradability of protein films is associated with the film composition and the extent of covalent cross-linking. WPI films buried in a compost pile began to degrade in two days and became darker over time. More than 80% of total solids were lost in 7 days.     

堆肥修复土壤金属污染研究进展

堆肥是有机废弃物资源化的产物,利用堆肥修复土壤的金属污染有着重大意义.堆肥可通过直接与金属产生氧化还原作用、沉淀作用、吸附作用或间接改变土壤理化性质如酸碱度,氧化还原电位等降低土壤金属的生物有效性和移动性,但具体修复效果因土壤、金属、堆肥三者性质的不同而差异甚大.本文对国内外利用堆肥修复土壤金属污染的研究进展进行了综述,指出了理论研究和实际修复中存在的一些问题,并对其发展前景进行了展望.