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121.
122.
L. NEIL FRAZER 《Conservation biology》2009,23(3):599-607
Abstract: A sea cage, sometimes referred to as a net pen, is an enclosure designed to prevent farm fish from escaping and to protect them from large predators, while allowing a free flow of water through the cage to carry away waste. Farm fish thus share water with wild fish, which enables transmission of parasites, such as sea lice, from wild to farm and farm to wild fishes. Sea lice epidemics, together with recently documented population‐level declines of wild salmon in areas of sea‐cage farming, are a reminder that sea‐cage aquaculture is fundamentally different from terrestrial animal culture. The difference is that sea cages protect farm fish from the usual pathogen‐control mechanisms of nature, such as predators, but not from the pathogens themselves. A sea cage thus becomes an unintended pathogen factory. Basic physical theory explains why sea‐cage aquaculture causes sea lice on sympatric wild fish to increase and why increased lice burdens cause wild fish to decline, with extirpation as a real possibility. Theory is important to this issue because slow declines of wild fish can be difficult to detect amid large fluctuations from other causes. The important theoretical concepts are equilibrium, host‐density effect, reservoir‐host effect, and critical stocking level of farmed fish (stocking level at which lice proliferate on farm fish even if wild fish are not present to infect them). I explored these concepts and their implications without mathematics through examples from salmon farming. I also considered whether the lice‐control techniques used by sea‐cage farmers (medication and shortened grow‐out times) are capable of protecting wild fish. Elementary probability showed that (where W is the abundance of wild fish, W* is the prefarm abundance, F is the abundance of farm fish, and is the ratio of lice per farm fish to lice per wild fish). Declines of wild fish can be reduced by short growing cycles for farm fish, medicating farm fish, and keeping farm stocking levels low. Declines can be avoided only by ensuring that wild fish do not share water with farmed fish, either by locating sea cages very far from wild fish or through the use of closed‐containment aquaculture systems. These principles are likely to govern any aquaculture system where cage‐protected farm hosts and sympatric wild hosts have a common parasite with a direct life cycle. 相似文献
123.
盐碱湿地鲇鱼资源及其增养殖 总被引:1,自引:0,他引:1
鲇鱼是松嫩平原盐碱湿地重要的高值食用鱼类之一。根据近年来对新荒泡鲇鱼的研究,作者报道了其生物学特征、经济价值、资源利用现状及其对新荒泡渔业资源的影响,提出了鲇鱼的增养殖途径及其关键技术。 相似文献
124.
可持续发展是我国发展战略与国策,我国水产通过繁殖保护、增殖水产资源;发展与强化水产养殖,扩大与充分利用养殖水体;综合养殖,特别是渔业生态工程等高速大幅度增产多种水产品,提高人民生活水平,增加经济收入,促进一些物质的良性循环,从而对可持续发展有所贡献,但其中有些部分忽略了水产所依托的水生态系统的整体性、协调性和稳态,导致人与自然在某些方面失调,不利于可持续发展。本文着重从一些生态学方面分析这些贡献和问题,并举一些例证加以论述。 相似文献
125.
以颗粒活性炭为填料,采用盐度梯度两步驯化法构建含盐水体生物滤器硝化功能,研究了生物滤器稳定后水力停留时间(hydraulic retention time,HRT)、进水氨氮负荷和CODMn/N等对反应器硝化性能的影响。结果表明,25~27℃,盐度30的含盐水体生物滤器硝化功能构建需73 d,其中淡水生物滤器硝化功能构建需28 d,淡水驯化为盐度15的生物滤器需19 d,盐度15驯化为盐度30的生物滤器需26 d;实验条件下生物活性炭填料反应器中生物量达到146~742.1 nmolP/g-BAC;调节进水氨氮浓度2 mg/L左右时,最佳HRT为1 h,氨氮去除率达到84.98%,相应的氨氧化菌和硝酸菌氧吸收速率(oxygen uptake rate,OUR)分别为2.091和1.948 mg O2/(g-BAC.h);HRT为1 h时,随着进水氨氮负荷的加大,氨氮去除率逐渐降低,当进水氨氮负荷由0.12增加到0.48 g-N/(kg-BAC.d)时,氨氮去除率由84.98%降低到41.68%,同时氨氧化菌OUR由2.091降低到0.625 mg O2/(g-BAC.h);随着CODMn/N的升高,氨氮去除率下降,CODMn/N从1~8时,氨氮去除率由84.98%降低到53.64%,CODMn去除率却逐渐增加,由40.86%增加到93.59%,异养菌OUR随着CODMn/N升高呈上升趋势,最大达到0.914 mg O2/(g-BAC.h)。 相似文献
126.
Ju L. Gan Xiao P. Jia Ting Jia Qin Lin Wen G. Cai 《Journal of environmental science and health. Part. B》2013,48(8):817-822
This investigation was undertaken to understand the temporal trend, the spatial distribution and the residue level of dichloro-diphenyl-trichloroethanes (DDTs) and hexachlorobenzenes(HCHs) in bivalves from the coast of the South China in recent years. Jinjiang oysters (Crassostrea rivularis) were sampled from 15 bays along the coast of Guangdong province, China between 2003 and 2007. Gas chromatography with electron capture detector was used to quantify the contents of HCH isomers (α-, β-, γ-, δ-HCH), DDT isomers (p,p′-, o,p′-DDT), p,p′-DDD and p,p′-DDE in the oyster tissues. The results demonstrate that annual level of DDTs in the tissue increase throughout the study, particularly between 2004 and 2006. The DDTs content in the tissue varied significantly among sampling regions and some sampling sites (p < 0.05). On the other hand, the HCHs content was significantly lower than DDTs content in the tissue (p < 0.01), and remain constant among sampling years, sampling regions and sampling sites (p > 0.10). Predominance of isomer form of DDTs and higher ratio of γ-HCH/HCHs at some sites indicated that recent input of DDT and lindane in the coastal waters of Guangdong, which might be caused by dicofol spraying in crop planting and lacquer painting on fisher boat. In the soft tissues of the oysters, the highest content of HCHs was 1.21 ng/g (wet weight), and DDTs levels ranged from 0.11 ng/g to 76.3 ng/g (wet weight), far below the Maximum Residual Limits in China and many developed nations. 相似文献
127.
Gerald L. Kurten Aaron Barkoh Drew C. Begley Loraine T. Fries 《Journal of the American Water Resources Association》2010,46(1):170-186
Kurten, Gerald L., Aaron Barkoh, Drew C. Begley, and Loraine T. Fries, 2010. Refining Nitrogen and Phosphorus Fertilization Strategies for Controlling the Toxigenic Alga Prymnesium parvum. Journal of the American Water Resources Association (JAWRA) 46(1):170-186. DOI: 10.1111/j.1752-1688.2009.00401.x Abstract: Previous studies have shown that three times weekly applications of phosphorus (30 μg P/l) and nitrogen (300 μg N/l) were effective at reducing the density and toxicity of the alga Prymnesium parvum in limnocorrals simulating a 40-day moronid (e.g., striped bass, Morone saxatilis, and palmetto bass, M. saxatilis ×Morone chrysops) fingerling culture period. However, this fertilization regime produced high pH and unionized ammonia-N concentrations that are detrimental to the survival of moronid fry and fingerlings. In two follow-up experiments we changed the source of N from ammonia to nitrate, reduced fertilization rates, and examined the effect of N-only or P-only fertilization. In the first experiment P fertilization rates were reduced by one-half to 15 μg P/l and NO3-N was substituted for NH3-N at the previously used rate of 300 μg N/l. In the second experiment, N fertilization rates were reduced to 150 μg N/l and the frequency of fertilization was determined by pH and P. parvum responses. Nitrate appeared to be as effective as ammonia as a source of N and when used in combination with P reduced P. parvum cell density and ichthyotoxicity. However, reduced N and P application rates and lower pond water temperatures during the study appeared to have decreased the speed at which fertilization produced these effects. While lower fertilization rates reduced algal productivity, high pH remained a concern for fish culture although pH was reduced to levels that might be acceptable with careful management of fish culture activities. Neither N-only nor P-only fertilization had a measurable effect on algal productivity or eliminated P. parvum and its toxicity. Furthermore, P-only fertilization may have increased P. parvum density and toxicity. For controlling P. parvum density and ichthyotoxicity we recommend a fertilization rate of 212 μg NO3-N/l plus 30 μg PO4-P/l applied three times weekly for aquaculture ponds where high pH is not a concern. Where high pH is a concern we recommend a fertilization rate of 117 μg NO3-N/l plus 16 μg PO4-P/l applied three times weekly with careful attention to afternoon pond pH. 相似文献
128.
养殖池塘生态系统中磷的收支及解磷微生物的研究进展 总被引:2,自引:0,他引:2
综述了池塘养殖系统磷的收支情况.研究发现,在池塘养殖系统中,磷输出最主要的形式为底泥沉积,养殖池塘中存在着磷的总体利用效率不高,水体中活性磷含量低的问题.而解磷微生物的应用在一定程度上可有效解决上述问题,它们能将植物难以吸收利用的磷转化为可吸收利用的形态.通过阐述解磷微生物的种类、解磷效果及解磷机制,结合养殖池塘的情况,分析了将解磷微生物应用于水产养殖中的可行性,并对今后的研究方向作出了展望.结合我国水产养殖的实际情况,筛选适应池塘养殖环境的高效解磷微生物,并将其应用于池塘养殖中,使池塘沉积物中难溶性磷转化具备相当的可行性. 相似文献
129.
130.
利用菌-藻体系净化水产养殖废水 总被引:7,自引:7,他引:7
采用正交法确定由地衣芽孢杆菌、硝化细菌、月芽藻、四尾栅藻组成的菌-藻体系去除水产养殖废水中的CODCr,NH4+-N,NO2--N,NO3--N以及溶解态磷(DP)的最优化体积比.结果表明,地衣芽孢杆菌、硝化细菌、月芽藻、四尾栅藻接种量分别为2.01×106, 2.18×106, 1.95×106和1.89×106 cfu/mL,V(地衣芽孢杆菌)∶V(硝化细菌)∶V(月芽藻)∶V(四尾栅藻)为1∶2∶2∶2时,污染物的去除效果最佳,其中,CODCr,NH4+-N,NO2--N,NO3--N和DP的去除率分别为44.05%,89.16%,100%,98.62%和100%,投加菌-藻溶液的养殖废水污染物去除率优于其自身的净化效果.通过对体系中各因素极差分析得出,地衣芽孢杆菌是体系中去除CODCr和NO3--N的主要因素,月芽藻是去除NH4+-N的主要因素,四尾栅藻是去除NO2--N的主要因素,硝化细菌是去除DP的主要因素. 相似文献