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为减少高密度养殖下菲牛蛭疾病发生和养殖废水排放,研究比较了3种商品化有益微生物制剂(硝化细菌T1、光合细菌T2和EM复合菌T3)对菲牛蛭高密度养殖水体的净化效果。结果表明,3种有益微生物制剂在15天内均能使养殖水体的pH稳定在6.8以上,溶氧量(DO)分别比对照组提高30.12%(T1),26.95%(T2)和46.12%(T3),化学耗氧量(COD)分别比对照组低1.02 mg/L(T1)、1.13 mg/L(T2)和1.53 mg/L(T3);3个处理组对氨氮(NH4+ - N)的平均降解率分别为:48.48%(T1),45.23%(T2)和63.10%(T3),亚硝态氮(NO2- - N)平均值分别比对照组低:0.16 mg/L(T1),0.19 mg/L(T2)和0.27 mg/L(T3)。3个处理组菲牛蛭存活率均高达90%以上,明显高于对照组(53%)。3种有益微生物制剂均有显著增加溶氧量、降低氨氮、亚硝态氮和化学耗氧量的效应。因此,本研究中3种有益微生物对菲牛蛭养殖水体均具有很好的净化作用,其中以EM复合菌效果最佳。 相似文献
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不同生物絮团对脊尾白虾高密度养殖水体氨氮的影响 总被引:1,自引:0,他引:1
为筛选适宜虾类工厂化养殖使用的生物絮团种类,以脊尾白虾(Exopalaemon carinicauda)为实验材料,探讨了3种不同产地(河南、福建、河北)来源的EM菌产生的生物絮团对脊尾白虾高密度养殖水体氨氮(ammonia nitrogen, AN)浓度的影响。每种生物絮团下共设置600尾/m~3、800尾/m~3、1 000尾/m~3共3个养殖密度,实验周期为8 d。结果显示,应用河南产地的EM菌,在600尾/m~3、800尾/m~3、1 000尾/m~3养殖密度下,水体最终氨氮浓度为1.28 mg/L、1.52 mg/L、1.90 mg/L,日均节水率为50.1%;应用福建产地的EM菌,水体最终氨氮浓度为1.03 mg/L、1.48 mg/L、2.15 mg/L,日均节水率为52.2%;应用河北产地的EM菌,水体最终氨氮浓度为1.58 mg/L、1.78 mg/L、2.74 mg/L,日均节水率为24.4%;而对照组水体最终氨氮浓度分别为1.62 mg/L、2.12 mg/L、3.05 mg/L,以上3种生物絮团在脊尾白虾高密度海水养殖中均有降低水体氨氮的作用,且效果存在显著差异,揭示水产养殖过程中应对适宜的EM菌试剂进行筛选后使用。实验筛选获得了适合脊尾白虾高密度养殖的生物絮团,为进一步开展其工厂化养殖及节水减排提供了参考。 相似文献
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利用组合湿地系统对湖区池塘养殖尾水进行净化,以实现水体循环再利用,减少对周围水环境的污染。组合湿地系统由3个莲藕净化塘、1个生态沟渠和1个人工湿地组成,面积分别为2.1 hm2、1.47 hm2和0.52 hm2,其中净化塘莲藕的覆盖度分别为0%、30%、60%。沿程采样测定水化学指标。结果显示,组合系统能够有效降低养殖尾水中的总氮(TN)、总磷(TP)、氨氮(NH4+-N)和化学耗氧量(COD)等指标。TN、TP由初始值1.3 mg/L、0.76 mg/L降到0.4 mg/L、0.09 mg/L,去除率分别为41.5%、77.5%;NH4+-N、COD由初始值0.27 mg/L、42 mg/L降到0.06 mg/L、27 mg/L,去除率分别为77.7%、35%。研究表明,该组合湿地系统能有效净化养殖尾水,实现水体循环再利用,可有效缓解南四湖的入湖污染负荷。 相似文献
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为探究凡纳滨对虾(Litopenaeus vannamei)工厂化循环水养殖系统的养殖水体水质情况以及微生物菌群的组成结构,本研究利用高通量测序技术和生物信息学分析手段,测定凡纳滨对虾工厂化循环水养殖过程一级移动床生物净化、二级固定床生物净化、养殖水体的水质指标、水体和生物净化载体以及对虾肠道微生物菌群的组成。结果显示,水体的氨氮(NH4+-N)和亚硝态氮(NO2–-N)质量浓度显著降低,分别为0.85和0.21 mg/L。养殖系统水体、生物净化载体和虾肠道样品中共有的优势菌为变形菌门(Proteobacteria)、拟杆菌门(Bacteroidetes),此外,一级、二级生物净化系统水体中的放线菌门(Actinobacteria)为优势菌,生物净化载体中浮霉菌门(Planctomycetes)和硝化螺旋菌门(Nitrospirae)为优势菌;对虾肠道中的厚壁菌门(Firmicutes)为优势菌。另外,对虾养殖循环水系统中生物净化载体上的细菌物种含量比水样中的细菌物种少,但微生物多样性高于养殖水体,生物净化载体中微生物具有低丰度和高多样性的特点。综上所述,生物净化系统可有效地增加水体中促进氮、磷代谢的微生物菌群,调控养殖水体的水质指标,研究结果为凡纳滨对虾工厂化循环水养殖系统构建及水质调控提供理论依据。 相似文献
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三种微生态制剂对鱼池水质净化作用的对比试验 总被引:7,自引:0,他引:7
对比了三种微生态制剂对淡水养殖池的水质净化效果。试验结果表明:在提高水体的溶氧量方面,“高浓缩光合细菌”的效果极显著,比对照组提高了30%。“水产EM原液”和“益生菌”对水体的溶氧量无明显影响;在降低氨氮含量方面,“水产EM原液”和“益生菌”效果极显著,比对照组分别降低了82%,和81%。“高浓缩光合细菌”效果较显著,比对照组降低了69%;在提高池水的pH值方面,“水产EM原液”作用明显,较对照组提高4%,且不引起pH值剧烈波动。“高浓缩光合细菌”和“益生菌”对pH值的影响不明显;在降低池水的化学耗氧量方面,三种微生态制剂均未表现出显著作用。 相似文献
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以凡纳滨对虾(Litopenaeus vannamei)室内工厂化流水养殖(IIFA)为对照组,通过养殖场凡纳滨对虾循环水养殖(RAS)试验(85 d)比较不同养殖模式对凡纳滨对虾的生长性能、养殖水体水质影响,探究循环水养殖系统(RAS)的硝化效率变化。结果显示:RAS的凡纳滨对虾存活率(74.58%±1.74%)、饲料转化率(70.56%±3.82%)、产量(3.91±0.49 kg/m^3)显著高于IIFA的凡纳滨对虾存活率(66.90%±3.80%)、饲料转化率(67.14%±3.25%)、产量(3.47±0.42 kg/m^3)(P<0.05)。对虾RAS可以将养殖水体化学需氧量(COD)、氨氮(NH_4^+-N)和亚硝酸盐氮(NO_2^--N)质量浓度稳定在较低水平(5.92、0.60和1.14 mg/L);对照组的COD呈现上升趋势,最高升至15.37 mg/L,NH_4^+-N和NO_2^--N质量浓度在较大范围(0.20~2.90 mg/L和0.19~6.97 mg/L)内波动。然而,对虾RAS养殖水体NO_3^--N和总氮呈现逐渐上升的趋势,最高分别升至25.98和33.55 mg/L;对照组养殖水体NO_3^--N(0.94~2.85 mg/L)和总氮(5.95~14.01 mg/L)质量浓度变化则相对较小。对虾RAS对养殖水体硝化作用发挥着至关重要的作用,NH_4^+-N和NO_2^--N去除率分别为23.78%~91.43%和0~27.76%,NO_3^--N累积率则稳定在一定范围(0.57%~4.30%)。研究表明,对虾RAS的应用可有效控制凡纳滨对虾养殖水体关键水质指标,有利于对虾存活率的提高和养殖产量的增加。 相似文献
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通过对黄颡鱼养殖池塘水体主要水质因子周年变化的测定与比较,探讨黄颡鱼养殖对水体环境的影响。研究主要测定了水体总磷(TP)、磷酸盐(PO4-P)、硝酸盐氮(NO3-N)、亚硝酸盐氮(NO2-N)和氨氮(NH4-N)含量。结果表明:养殖水体TP全年变化范围为0.08~1.17mg/L,5月份TP含量最低。PO4-P全年变化范围为0.02~0.27mg/L,10-12月份PO4-P含量较高为0.24~0.27mg/L。NO3-N全年变化范围为0.02~11.67mg/L,8月和11月份形成2个峰值;NO2-N全年变化范围为0.02~0.48mg/L,10月份呈现最高值0.48±0.01mg/L。NH4-N全年变化范围为0.06~2.02mg/L,5月份呈现峰值。溶解态无机氮(DIN)全年含量为0.43~11.76mg/L,且从全年氮平均含量进行考察,NO3-N、NH4-N和NO2-N分别占DIN的78.16%、16.72%和5.12%,N/P比值在5月和11月份出现2个峰值。黄颡鱼养殖池塘的水体氮和磷营养含量受光照、水温和鱼体活动等因素影响。 相似文献
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四联活菌制剂对养殖水体中氨氮及亚硝酸盐的降解 总被引:3,自引:0,他引:3
利用四联活菌制剂,在室内进行了对养殖池塘水体中氨氮及亚硝酸盐的降解试验.结果表明,光合细菌、纳豆芽孢杆菌、乳酸菌、硝化细菌具有较好的氨氮、亚硝酸盐降解性能,随着添加质量浓度的增加,氨氮、亚硝酸盐的去除率增加;各菌株氨氮降解能力依次为:乳酸菌>光合细菌>硝化细菌>纳豆芽孢杆菌;亚硝酸盐降解能力依次为:硝化细菌>纳豆芽孢杆菌>光合细菌>乳酸菌.四联活菌制剂对养殖水体中氨氮及亚硝酸盐降解试验结果表明,乳酸菌、光合细菌、硝化细菌、纳豆芽孢杆菌的协同作用对氨氮、亚硝酸盐的降解效果更显著、快速.当制剂添加量分别为1.5、3.0、4.5 kg/hm~2时,5 d氨氮的去除率分别为52%、80%、74%,亚硝酸盐的去除率接近100%,结果均显著高于添加同剂量单一菌株时的氨氮、亚硝酸盐的去除率. 相似文献
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养殖尾水污染已成为制约水产养殖业发展的重要因素。填料生物膜养殖尾水处理系统是近年来开发的一种经济、高效去除养殖废水污染物的尾水处理设施。然而关于填料生物膜在氮素迁移转化中微生物生态效应及其功能知之甚少。为此,本研究利用宏基因组学方法剖析填料生物膜微生物群落氮循环过程及其潜在驱动机制。研究发现,填料生物膜微生物主要参与氮代谢活动。与水体相比,填料生物膜的碳代谢活动能力较强(P<0.05);填料生物膜上硝化作用羟胺还原酶、反硝化作用氧化亚氮还原酶和一氧化氮还原酶及其编码功能基因nosZ和norB、异化硝酸盐还原作用亚硝酸盐还原酶及其功能基因napA、nrfA和nirB、以及固氮酶及功能基因nif HDK丰度相对较高(P<0.05),说明填料生物膜具有比周围水环境更强的氮周转能力。在属水平上,Pseudomonas菌、Spirochaeta菌、Opitutus菌和Syntrophus菌是填料生物膜氮素转化关键过程的重要功能微生物类群。上述研究结果表明,养殖尾水处理系统内复合填料生物膜主要通过关键功能物种介导的固氮和反硝化作用实现养殖尾水氮素的转化和迁移。本研究结果作为野外实验证据可为今后复合填料生物膜系统在水产养殖尾水治理实践提供理论依据。 相似文献
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Aquaculture wastewater treatment and reuse by wind-driven reverse osmosis membrane technology: a pilot study on Coconut Island, Hawaii 总被引:3,自引:0,他引:3
Gang Qin Clark C.K. Liu N. Harold Richman James E.T. Moncur 《Aquacultural Engineering》2005,32(3-4):365-378
Nitrogen in aquaculture wastewater may cause many environmental problems to the receiving water. To protect its pristine coastal water, the State of Hawaii established stringent water quality limits for aquaculture wastewater. Effluents from aquaculture facilities in Hawaii generally exceed these limits—sometimes by one to two orders of magnitude. Development of cost-effective treatment technology would be one of the most important factors for a profitable aquaculture industry in Hawaii. Furthermore, recirculating of aquaculture wastewater is highly desirable for environmental protection and resource conservation. To achieve these goals, a wind-driven reverse osmosis (RO) technology was developed and applied for the removal of nitrogenous wastes from the culture water of tilapia on Coconut Island, the home of the Hawaii Institute of Marine Biology, University of Hawaii at Manoa. A conventional multi-blade windmill is used to convert wind energy directly to hydraulic pressure for RO membrane operation. Aquaculture wastewater passing through the RO membrane is separated into permeate (freshwater) and brine (concentrated wastewater). The permeate is recirculated to the fish tanks, while the brine is collected for possible treatment or reuse. As a result, no wastewater discharge is made to the ambient coastal water. Testing results indicated that the prototype wind-driven RO system can process and recycle freshwater at a flux of 228–366 L/h, depending on wind speed. The nitrogen removal rate ranges from 90% to 97%, and the recovery rate of the RO membrane is about 40–56%. A preliminary cost analysis shows that the production of 1.0 m3 permeate from aquaculture wastewater would cost US$ 4.00. Further study will focus on the reuse of concentrates and on further enhancement of cost-effectiveness. 相似文献
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光合细菌对三角帆蚌养殖水体水质的影响 总被引:4,自引:1,他引:4
将红螺菌科的红假单胞菌应用于三角帆蚌(Hyriopsis cum ingii)养殖水体,测定水化学环境因子和微生态群变化情况。结果表明,光合细菌可稳定养殖水体pH,去除氨氮、亚硝基氮、总氮,降低COD,改变水体氮磷比;光合细菌能有效控制异养细菌、弧菌、气单胞菌数量,对真菌的增殖也有一定抑制作用,避免养殖水体水质恶化。 相似文献
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Phosphatase activity with reference to bacteria and phosphorus in tropical freshwater aquaculture pond systems 总被引:6,自引:0,他引:6
The bio‐geochemical cycle of phosphorus is significantly influenced by microbes in the aquatic environment. Organic phosphorus compounds are decomposed and mineralized by enzymatic complexes such as phosphatases produced by microbes. Enzymatic catalysis results in the production of orthophosphate, which can be used readily by primary producers. Even the smallest concentration of phosphate in water has an influence over the production process in aquaculture systems. Extracellular alkaline phosphatase activity was observed in water and sediment media of aquaculture ponds with different management practices. Heterotrophic bacterial populations as well as phosphatase‐producing bacterial populations were higher in sediments compared with water. In the freshwater fish ponds, Bacillus spp. were the dominant forms of bacteria producing phosphatase. The alkaline phosphatase activity of sediment was always higher than that of water. The partitioning of extracellular alkaline phosphatase in pond water by a 0.22‐µm membrane filter revealed that a proportion was often free rather than cell associated and might have originated as free enzymes released by enriched sediments or by fish or microbes. In the case of water, although the dissolved alkaline phosphatase activity was lower than the total alkaline phosphatase activity, the former was nevertheless unimportant, as it constituted about 20% of the ‘total’ activity. Free alkaline phosphatase activity shared a negative correlation with the orthophosphate concentration of water, whereas gross alkaline phosphatase activity was positively correlated with the total phosphorus and bacterial population of water. 相似文献
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为研究絮团浓度对革胡子鲇零换水养殖效果的影响,在不额外添加有机碳源(只利用饲料中的碳)的革胡子鲇()养殖系统中,设置了平均絮团质量浓度为561.18 mg/L和780.41 mg/L两个处理组,比较了两实验组的水质、菌群结构、鱼生长及氮利用效率。结果表明,两种浓度絮团条件下,总氨氮(total ammonia nitrogen,TAN)和亚硝酸氮(NO2--N)能分别维持1.84 mg/L和1.79 mg/L以下。两处理组间pH、溶解氧(dissolved oxygen,DO)、TAN、NO2--N、氮素利用效率及主要生长指标无显著差异(-N)浓度(822.0 mg/L)明显高于低浓度絮团组(623.33 mg/L)。高通量测序分析菌群结构结果表明,两组间门水平的菌群组成种类及优势度无显著性差异(<0.05)。两处理组中的革胡子鲇存活率分别达到(91.11±1.53)%和(94.44±2.08)%,饲料系数为(1.41±0.18)和(1.27±0.26),特殊生长率为(2.13±0.04)%/d和(2.19±0.08)%/d,均无显著差异(>0.05)。两实验组饲料氮的利用率分别达到了72.17%和71.34%。综合以上结果认为,仅利用饲料中的碳既能维持革胡子鲇的零换水养殖且能取得较高的氮素利用效率,两种絮团浓度对革胡子鲇的生长无显著影响,高浓度絮团组中的硝化作用更明显。 相似文献
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Aquaculture has evolved as the fastest growing food-producing sector and developed as an important component in food security.
To keep a sustainable growth pattern, health management strategies must go beyond antibiotics and chemotherapeutics, which
create resistant bacteria and immunosuppression in the host. Besides development of drug resistant bacteria and pathogens,
the adverse effect of antibiotics is caused by their influence on the aquatic microflora, and the retention of harmful residues
in aquatic animals. On the other hand, the microbes with their unique structure and cell wall components can trigger immunity,
and thus exposure plays an important role in the evolution. Microbial intervention through an environmentally friendly approach
is an alternative method of health management. India is endowed with a bounty of varied climatic conditions, microbial diversity
and fish fauna and aquaculture systems offering challenges in biological and environmental pursuits. Producing about 4.4%
of world’s fish and ranking third in global fish production, India trades about 2.4% in global fish market with the annual
export earning being over $1311 million. Use of microbes for beneficial purposes is increasingly recognized as a valuable
input for sustainable and responsible aquaculture. Microbial intervention in aquaculture can be broadly water/environment
based through bioaugmentation, biostimulation, biocontrol measures, or (to generate) host response through probiotics, immunostimulants,
and vaccines. Also, application of molecular methods such as polymerase chain reaction (PCR) and nucleic acid techniques are
making increasing inroads into aquatic microbiological research in India. This paper elucidates all these aspects of microbial
intervention in aquaculture, high-lighting Indian research and accomplishments. 相似文献
19.
为探求衢州市渔业水域水库水体富营养化水平和主要驱动因子,本研究基于2018年水质监测数据,综合评价黄坛口水库(S1)、铜山源水库(S2)、狮子口水库(S3)、花园垄水库(S4)和金仓垅水库(S5)5座不同水库水体富营养化水平,并采用相关性分析、主成分分析探讨水质环境因子对水体富营养化水平间的影响和相关关系。结果显示,叶绿素a(Chl-a)与综合营养状态指数法评价结果趋于一致,表明S1、S2和S3水库均为中营养,S4为轻度富营养,S5为重度富营养,水产养殖水域富营养化水平显著高于增殖放流水域(P<0.05)。5个水库中,S5为氮限制,其余水库均为磷限制。多元线性逐步回归分析表明,Chl-a与溶解氧(DO)、透明度(SD)、铜(Cu)、总磷(TP)、总氮(TN)、高锰酸盐指数(CODMn)的相关性较好,综合营养状态指数(TLI)与水温(T)、SD、Cu、TP、TN的相关性较好,得到模型:Chl-a=19.793 CODMn-32.065 TP-33.004,TLI=1.062 CODMn+18.468 TP-0.06 SD+0.450 T+1.765 TN+33.886。综合相关性分析、主成分分析结果,CODMn、TP、SD、T和TN是影响衢州市水库水体富营养化的主要因子,其中,氮、磷营养盐和有机物是造成水库水体富营养化的主要影响因子,水温是造成各水库富营养化季节性变化的主要原因,而pH、溶解氧是水体富营养化后的结果,可以作为水库富营养化水平的指示因子。 相似文献