施用牛粪对As污染稻田水稻As吸收的影响

为探究牛粪施肥对污染稻田水稻As吸收的影响,采用盆栽培养试验研究了施加牛粪对土壤Fe和As的活性、水稻根表铁膜形成及籽粒As含量的影响。实验所用受高As矿山废水污染土壤(As:92. 3 mg/kg)施加10%～30%的牛粪,土壤溶解性有机碳含量增加8. 41～24. 5 mg/kg,土壤孔隙水pH提高0. 14～0. 59,土壤氧化还原电位降低93. 5～174 m V,与背景土(As:18. 1 mg/kg)变化趋势相同;施用牛粪还会活化土壤中的Fe和As,污染土壤Fe(II)、AO-Fe和HCl-As含量分别增加13. 5%～149%、35. 9%～90. 9%和70. 1%～181%,分别为背景土壤的0. 86～1. 66倍、1. 17～2. 15倍、4. 29～8. 91倍;施加牛粪能促进根表铁膜的形成,拔节期污染土壤和背景土壤水稻根表Fe分别是其对照的1. 56～1. 96倍和2. 09～3. 07倍,根表吸附As含量是其对照的3. 04～5. 18、3. 82～4. 08倍,根表附着Fe随牛粪的增加先增加后降低,至成熟期污染土壤水稻根表吸附Fe和As分别是背景土壤的1. 35～2. 91和8. 45～16. 6倍,根表As和Fe的物质量比为污染区(3. 49×10~(-3)～3. 55×10~(-3))背景区(4. 41×10~(-4)～6. 17×10~(-4));背景土壤施加牛粪后水稻籽粒As含量降低,最大降低36. 4%,而污染土壤水稻籽粒As含量增加,最大增加127%。牛粪对土壤As、Fe的活性及根表铁膜的形成都具有重要影响,会提高污染稻田籽粒中As的含量,含As矿山废水污染稻田应当谨慎施用牛粪。     

黄淮海地区鸡粪有机肥重金属含量特征及环境风险

本文调查黄淮海地区5省2市120种商品鸡粪有机肥样品,分析测定有机肥中Cu、Cd、Pb、Zn和As含量、形态分布以及浸提毒性.结果表明,有机肥中重金属含量差异较大,表现为ZnCuPbAsCd,与有机肥行业标准相比,Cd、As、Pb存在超标现象,分别为6.7%、47.05%和14.28%,不同省市间重金属含量差异明显.有机肥中Cd、Zn主要以铁锰结合态存在,分别占37.3%和43.79%(质量分数),而残渣态Pb、有机结合态Cu,交换态As比例较高.有机肥中TCLP-Zn、-Cu、-Cd、-Pb和-As含量分别为41.11、3.33、0.07、1.25和0.21 mg·kg~(-1),有机肥中Zn和Pb含量超标数为6和5个,分布在河北省和江苏省.有机肥中Zn、Cu、Cd和As总量与TCLP提取态含量存在显著相关性(P0.05).按鸡粪有机肥年施肥量15t·hm-2推算鸡粪有机肥安全使用年限:河南天津安徽=山东=江苏河北北京.     

CANON工艺处理猪场沼液的启动及微生物种群结构分析

在连续流合建式反应器内接种普通活性污泥,以实际猪场沼液作为进水,保持温度为(30±1)℃,控制低溶解氧(DO浓度为(0.5±0.1)mg·L~(-1)),通过分阶段提高氨氮浓度的方式启动CANON(Completely autotrophic nitrogen removal over nitrite)工艺,同时采用高通量测序技术对反应器启动前后的微生物种群结构进行分析.结果表明,反应器可在210 d实现成功启动CANON工艺,启动成功后,当猪场沼液进水氨氮浓度为450 mg·L~(-1)时,氨氮和总氮的去除率分别达到69.8%和61.1%;出水(NO_3~--N+NO_2~--N)/ΔNH_4~+接近0.11.同时,CANON工艺启动成功后,微生物种群结构发生了很大的变化:其优势菌门为变形菌门(Proteobacteria)(36.16%)、绿弯菌门(Chloroflexi)(14.22%)、浮霉菌门(Planctomycetes)(11.07%)、酸杆菌门(Acidobacteria)(10.41%)和绿菌门(Chlorobi)(12.82%);与脱氮功能相关的菌属为Candidatus_Brocadia (ANAMMOX菌)、Nitrosomonas(AOB菌)、Comamonadaceae(反硝化菌)和Xanthomonadaceae(反硝化菌)等.     

不同催花肥对莲雾根际土壤细菌群落多样性的影响

为了解在反季节催花期间不同催花肥处理下莲雾根际土壤细菌群落结构的影响,采用Illumina MiSeq高通量测序技术对细菌16S rRNA V3-V4区进行检测,并结合土壤理化性质,比较分析不施肥（CK）与两种不同浓度施肥处理组（IF组,即无机肥处理组;GM组,即羊粪有机肥处理组）下的根际土壤细菌群落结构多样性.结果表明:①所有样品中共检测到10 925个OTU（operational taxonomic unit,操作分类单元）,包括239 639条有效序列,可分为28个门411个属.②多样性指数分析显示,细菌群落多样性顺序为IFM（中浓度无机肥处理）> GML（低浓度羊粪有机肥处理）> IFL（低浓度无机肥处理）> GMM（中浓度羊粪有机肥处理）> CK（对照）> IFH（高浓度无机肥处理）> GMH（高浓度羊粪有机肥处理）.其中,酸杆菌门（Acidobacteria）、绿弯菌门（Chloroflexi）、变形菌门（Proteobacteria）、放线菌门（Actinobacteria）为主要菌群,所占比例超过总数的67.33%.③不同施肥条件下莲雾根际土壤细菌群落结构特征分析显示,CK、IF组和GM组所特有的OTU数量分别占总数的0.51%、7.08%和2.60%,表明不同肥料的添加对土壤细菌群落多样性产生一定的影响,在IFH和GMH处理下,酸杆菌门的Subgroup_2_norank属与绿弯菌门的JG37-AG-4_norank属的相对丰度最高,分别为13.13%和15.89%.④环境因子的相关性热图分析表明,装甲菌门（Armatimonadetes）、硝化螺旋菌门（Nitrospirae）、酸杆菌门、放线菌门、厚壁菌门（Firmicutes）这五类菌群与不同环境因子的显著性关系如下:装甲菌门群落结构与pH呈现出极显著正相关,硝化螺旋菌门群落结构分别与w（TN）和w（有机质）呈现出显著负相关,酸杆菌门群落结构与w（速效磷）呈现出显著负相关,放线菌门群落结构与w（速效磷）呈现出显著正相关,厚壁菌门群落结构分别与w（速效磷）和w（速效钾）呈现出极显著正相关.研究显示,适量施加无机肥或羊粪有机肥,可以显著提高土壤细菌的丰度和多样性,有利于土壤生态环境的改良与维系.      

Effects of chlortetracycline, Cu and their combination on the performance and microbial community dynamics in swine manure anaerobic digestion

Swine manure was typical for the combined pollution of heavy metals and antibiotics. The effects of widely used veterinary antibiotic chlortetracycline(CTC), Cu and their combination on swine manure anaerobic digestion performance and microbial community have never been investigated. Thus, four 2 L anaerobic digestion reactors were established including reactor A(control), B(CTC spiked by 0.5 g/kg dry weight, dw), C(Cu spiked by 5 g/kg dw) and D(combination of CTC, 0.5 g/kg dw, and Cu, 5 g/kg dw), and dynamics of bacterial and archaeal community structure was investigated using high throughput sequencing method. Results showed that addition of CTC and Cu separately could increase the total biogas production by21.6% and 15.8%, respectively, while combination of CTC and Cu severely inhibited anaerobic digestion(by 30.3%). Furthermore, corresponding to different stages and reactors, four kinds of microbes including bacteria and archaea were described in detail, and the effects of CTC, Cu and their combination mainly occurred at hydrolysis and acidification phases. The addition of Cu alone changed the dynamics of archaeal community significantly. It was genus Methanomassiliicoccus that dominated at the active methane production for A, B and D, while it was genus Methanobrevibacter and Methanoculleus for C.     

基于GIS的安徽省耕地畜禽养殖废弃物氮负荷估算及污染潜势研究

利用2012年安徽省各县市区的畜禽养殖统计数据及耕地面积,估算了安徽省畜禽养殖废弃物氮负荷,并利用德尔菲法和层次分析法确定了安徽省耕地畜禽养殖废弃物氮养分污染潜势评价的影响因素及权重,在此基础上,利用GIS空间分析技术对安徽省耕地畜禽养殖废弃物氮养分污染潜势进行了评价分析。结果表明,2012年安徽省的耕地畜禽养殖废弃物氮负荷分布很不均匀,最大值为217.08kg/hm~2,最小值24.27kg/hm~2,平均值为81.99kg/hm~2。绝大部分县市区都未超过170kg/hm~2的限量标准,但太湖县、歙县、砀山县和宁国市分别达到了217.08、212.76、197.82和192.95kg/hm~2。从空间特征看,安徽省各县市区耕地畜禽养殖废弃物氮养分污染潜势评价结果差异较大,大部分区域都属于一般等级以下,污染潜势高的区域主要分布在安徽省的东南部及西部的山地丘陵区,主要包括宁国市、歙县和太湖县,污染潜势较高的区域有长丰县、休宁县、绩溪县、黄山市市辖区、金寨县、岳西县、明光县及潜山县的部分区域。     

Dairy Manure Treatment,Digestion and Nutrient Recovery as a Phosphate Fertilizer

A combined approach of biological treatment, solids digestion and nutrient recovery was tested on dairy manure. A sequencing batch reactor (SBR) was operated in three modes, in order to optimize nutrient (nitrogen and phosphorus) removals. The highest average removal efficiencies of 91% for NH₄-N, 59% for PO₄-P and 80% for total chemical oxygen demand (COD) were achieved. Staining experiments suggested the coexistence of glycogen and phosphorus accumulating organisms. Anaerobic digestion of wasted bio-solids was able to produce a PO₄-P concentration of 70 mgL^?1 in the supernatant. A pilot-scale experiment, designed to recover phosphorus in the supernatant as struvite (magnesium ammonium phosphate), was able to remove 82% of soluble PO₄-P.     

Characterizing food waste substrates for co-digestion through biochemical methane potential (BMP) experiments

Co-digestion of food waste with dairy manure is increasingly utilized to increase energy production and make anaerobic digestion more affordable; however, there is a lack of information on appropriate co-digestion substrates. In this study, biochemical methane potential (BMP) tests were conducted to determine the suitability of four food waste substrates (meatball, chicken, cranberry and ice cream processing wastes) for co-digestion with flushed dairy manure at a ratio of 3.2% food waste and 96.8% manure (by volume), which equated to 14.7% (ice-cream) to 80.7% (chicken) of the VS being attributed to the food waste. All treatments led to increases in methane production, ranging from a 67.0% increase (ice cream waste) to a 2940% increase (chicken processing waste) compared to digesting manure alone, demonstrating the large potential methane production of food waste additions compared to relatively low methane production potential of the flushed dairy manure, even if the overall quantity of food waste added was minimal.     

Improved biogas production from rice straw by co-digestion with kitchen waste and pig manure

In order to investigate the effect of feedstock ratios in biogas production, anaerobic co-digestions of rice straw with kitchen waste and pig manure were carried out. A series of single-stage batch mesophilic (37 ± 1 °C) anaerobic digestions were performed at a substrate concentration of 54 g/L based on volatile solids (VS). The results showed that the optimal ratio of kitchen waste, pig manure, and rice straw was 0.4:1.6:1, for which the C/N ratio was 21.7. The methane content was 45.9–70.0% and rate of VS reduction was 55.8%. The biogas yield of 674.4 L/kg VS was higher than that of the digestion of rice straw or pig manure alone by 71.67% and 10.41%, respectively. Inhibition of biogas production by volatile fatty acids (VFA) occurred when the addition of kitchen waste was greater than 26%. The VFA analysis showed that, in the reactors that successfully produced biogas, the dominant intermediate metabolites were propionate and acetate, while they were lactic acid, acetate, and propionate in the others.     

利用光微生物燃料电池实现养猪废水资源化利用研究

采用光合细菌和微藻分别作为阳极和阴极接种物构建了双室光微生物燃料电池,考察了氮、磷浓度及阳极处理后的养猪废水对阴极微藻生长的影响,探讨了构建的光微生物燃料电池产电性能及去除养猪废水中COD、氨氮和总磷的效果.结果表明,阴极微藻不仅能利用无机硝态氮和氨氮,而且更喜好有机氮尿素;此外,阴极微藻可适应较高浓度的氮(250 mg·L-1)和磷(64.8 mg·L-1).构建的光微生物燃料电池以养猪废水为基质,外载为1000Ω时,稳定输出电压为161 m V;养猪废水的COD、氨氮及总磷去除率分别为91.8%、90.2%和81.7%.养猪废水经阳极光合细菌处理后培养微藻16 d,藻细胞光密度(OD680)可达3.40,略低于对照BG11培养基.因此,构建的光微生物燃料电池在处理养猪废水产电的同时,可收获微藻实现养猪废水资源化.