水产养殖活动中N2O的排放研究进展

本文分析了养殖水体氮转化过程中可能产生N_2O的环节,总结了关于水产养殖活动中N_2O排放量的相关研究进展。结果表明,养殖过程中的N_2O排放系数总体上低于废水处理过程中的N_2O排放系数;不同的养殖模式氮的利用效率及未被利用的氮的去向有较大差别,其中循环水养殖模式的氮处理过程最接近于废水处理厂中的处理途径,但循环水养殖产量占全球水产养殖产量的比例较低,且现有水产养殖总产量中约有一半的渔获物不需要投饵,因此,基于废水处理厂的N_2O排放系数和总养殖产量的N_2O排放量的估算会明显高于实际排放量。目前尚缺乏关于水产养殖N_2O产生的基础性研究,本研究未进行相关估算。应尽快开展水产养殖活动中产生N_2O的系统性研究,为客观评估养殖活动N_2O的排放提供理论支撑。     

以CFD-DEM为基础的养殖槽排污性能及底坡优化

由于能提高资源利用率,减少环境污染,低碳高效池塘循环流水养殖(IPA)作为一项新型养殖技术被大力推广。为了提高养殖过程中的集污排污效率,本研究拟采用构造负坡底面的方法对养殖槽结构进行优化。通过建立二维养殖槽简化模型,结合计算流体力学—离散单元法(CFD-DEM)模拟计算与核偏最小二乘(KPLS)建模方法,建立槽内垂向流速分布与底面坡度和粗糙度的关系模型。在此基础上结合泥沙运动理论,获得了槽内颗粒起动流速与单宽输沙率模型,在构建颗粒起动和输运两方面的性能指标后,利用基于偏好的多目标粒子群算法(DP-MOPSO)寻求最优底面坡度。寻优结果显示,随着底面粗糙度的增加,最优坡度略有减小,范围为0.013~0.015;仿真实验结果显示,构造最优底坡可有效提高颗粒的起动概率和槽体的颗粒运输能力,且对于表面较为粗糙槽体,坡型底面在颗粒起动方面的优越性更为显著,说明通过构建底坡来改变水流结构,从而实现养殖槽排污性能的优化是合理的。     

凡纳滨对虾养殖环境及肠道微生物群落特征分析

为探究凡纳滨对虾养殖过程中其肠道和养殖环境微生物群落的结构及变化,本实验采用Illumina MiSeq测序平台,基于16S rRNA基因的测序结果,对46和86 d虾龄的凡纳滨对虾肠道以及养殖水样、底泥中的微生物群落进行分析。结果显示,86 d时微生物Shannon-Wiener多样性指数显著高于46 d,水样中的Shannon-Wiener指数显著低于底泥和凡纳滨对虾肠道;有35个门、70个纲、152个目、274个科以及420个属在水样、底泥和虾肠道中均能检测到,其中虾肠道和底泥间共有菌类较水样中更多。微生物群落随养殖时间增加发生变化,46与86 d的差异性门类为放线菌门、绿菌门、丝状杆菌门、浮霉状菌门和TM6,相对丰度随时间增加而增高。水样、底泥和虾肠道中有相对固定的优势菌群,在水样、底泥和虾肠道中主要的门类均为变形菌门、拟杆菌门和放线菌门,优势纲类为α变形菌纲、β变形菌纲以及放线菌纲,除此以外,虾肠道与底泥共有的优势纲为δ变形菌纲、γ变形菌纲以及芽单胞菌纲;从目、科、属的分类水平上看,水样、底泥和虾肠道中菌类相对丰度各异,鲜有明显重叠的优势菌类,在水样、底泥和虾肠道中均为一种未分类的属占优势地位,水样中优势属为hgcI_clade,底泥和虾肠道中优势属为Ambiguous_taxa。研究结果进一步解释了虾肠道和环境微生物群落结构之间的相关性以及随虾龄增长呈现的差异性。     

鲆鲽类苗种技术创新与推广对策——基于生产者技术需求调研的思考

苗种是水产养殖生产的基础资料,苗种科技创新与推广的有效程度直接影响到产业可持续发展。以作为我国海水鱼类代表的鲆鲽类养殖业为例,基于养殖生产者的技术需求调研结果,提出了该产业苗种技术创新与推广的策略,即以市场为导向,始终将苗种科技创新作为重要的产业发展战略;密切结合产业发展转型战略,有效对接产业差别化需求,有差别地重点推进快速生长苗种、强抗逆性苗种以及全雌化优质苗种的培育与推广;因地制宜推进特色品种苗种培育,为塑造区域性鲆鲽类产品品牌提供支撑;认真做好战略储备性品种的苗种培育,切实推进产业的梯度发展;密切关注我国近海渔业资源修复之需求,培育适于增殖放流的鲆鲽类苗种。     

Completion of the Pacific bluefin tuna Thunnus orientalis (Temminck et Schlegel) life cycle

Tuna aquaculture is currently dependent on the wild capture of juveniles for production. The development of hatchery technology for bluefin and other tunas would be a major step forward in improving sustainability of their aquaculture. The present study overviews the technology in the life cycle completion of the Pacific bluefin tuna (PBT) Thunnus orientalis (Temminck et Schlegel) under aquaculture conditions in Kinki University, and the problems to be solved for the establishment of tuna hatchery technology. On 23 June 2002, broodstock of PBT that were artificially hatched and reared spontaneously spawned in captivity. The resulting eggs hatched and were subsequently reared to the juvenile stage. The spawning fish were the result of a research project started in 1987 to rear wild‐caught juvenile PBT that were several months old. Fertilized eggs were obtained from these fish in 1995 and 1996. Resulting juveniles (the artificially hatched first generation) were reared to maturity and spawned in 2002. Over the summer of 2002, 1.63 million eggs from these fish were used for a mass rearing experiment, and 17 307 juveniles were produced and transferred to an open sea net cage. Of these artificially hatched second‐generation PBT, 1100 grew to approximately 95 cm total length and 14 kg body weight in 22 months. This procedure means the completion of PBT life cycle under aquaculture conditions, which was first attained among large tuna species. The problems awaiting solution in PBT hatchery production are their unpredictable spawning in captivity, to improve survival during the first 10 days post hatch, to reduce cannibalism in larval and juvenile stages, and to solve collision problem causing high mortality during the juvenile stage.     

Study on an integrated eco‐aquaculture system for rearing the yellow seahorse,Hippocampus kuda Bleeker

Seahorse aquaculture is challenged by insufficient feeding supply and lack of biological and nutritional knowledge, resulting in low survival rate and poor economical profitability. We report here an integrated eco‐aquaculture system in which the yellow seahorse and its natural prey were co‐cultured with fertilized water and seaweed in cement ponds. In the first stage, urea (10 g m^?3) and chicken manure (50 g m^?3) were used to fertilize the cultured water, 5–7 days later, rotifer and micro‐crustaceans were flourishing. Then, seahorse juveniles were stocked at 200 ind m^?3. After 2 weeks, seaweed Gracilaria lichevoides was transplanted into the ponds to regulate water quality, light and to provide holdfast attachment for seahorses. The optimal density of G. lichevoides was controlled between 0.5 and 2 kg m^?3. The introduction of seaweed provides the habitat for natural food of seahorse. Within the cluster of the seaweed, small crustacean density was over 450 individuals per 100 g of fresh weight. Initial size of seahorse juvenile was 1.03 ± 0.091 cm, After the 146‐day rearing period, seahorse survival rates were 70.8%, 57.7% and 42.5%, and body standard lengths were 11.33 cm, 10.84 cm and 10.04 cm in the integrated eco‐aquaculture system (GFA) and in monoculture systems of FA (fertilized + feeding) and BA (only feeding) respectively. This system incorporated traditional Chinese aquaculture technique in which feedings nature food organisms were cultivated by fertilization and ecological regulation. Results from these preliminary experiments suggest that the integrated system could be technically feasible, suitable and exemplary.     

Effects of feeding rate and frequency on growth performance,digestion and nutrients balances of Atlantic salmon (Salmo salar) in recirculating aquaculture systems (RAS)

A 10‐week study was conducted to investigate the effects of feeding rate and frequency on growth performance, digestion and nutrients balances of Atlantic salmon (Salmo salar) in replicated recirculating aquaculture systems (RAS). Replicated groups of juvenile salmon weighing 90 ± 2.5 g (mean ± SD) were fed a commercial feed (21.63 MJ kg^?1 gross energy) to designed feeding rate (1.4%, 1.6% and 1.8% body weight day^?1, BW day^?1) and feeding frequency (2 and 4 meals day^?1) combinations. Specific growth ratio varied between 1.15 ± 0.02 and 1.37 ± 0.16% day^?1, and feed conversion ratio ranged from 0.96 ± 0.03 to 1.16 ± 0.02. The nitrogen and phosphorus retention rates were from 36.50 ± 1.94 to 47.08 ± 5.23% and from 20.42 ± 1.05 to 38.59 ± 2.80%. Apparent digestibility coefficients (ADC) in dry matter, protein, lipid and energy showed no significant differences for all groups. However, fish fed at 1.6% BW day^?1 and 4 meal day^?1 groups had relatively better growth and nutrient retention efficiency compared to other groups. In addition, concentrations of nitrogenous and phosphorous compounds were also detected in this study. These results suggested that salmon of 100–200 g in RAS could in practice be fed at 1.6% BW day^?1 and 4 meals day^?1, taking environmental impacts into account.     

海马齿对海水养殖系统中氮、磷的移除效果研究

大量的外源性饵料和排泄物使海水养殖水体N、P以及有机物大量增加,导致水质恶化,是制约海水养殖业发展的主要因素。通过构建海马齿面积比为3∶2盐度为15的A、B 2组浮床海水养殖系统,以检验海马齿的N、P移除能力。结果显示,当海马齿处于生长启动期,A组和B组的水质指标与对照组之间无显著性差异（P〉0.05）;但当海马齿生长...     

我国水产养殖节能减排问题分析

节能减排是实现可持续发展、人与自然和谐相处的关键。节能减排对于我国资源保护、环境保护、国际市场竞争能力、经济社会的可持续发展等都具有深远的意义。水产养殖在为人类提供水产品的同时,也对环境排放相应的污染物、造成能耗。在分析我国水产养殖排放、能耗及存在问题的基础上,提出实现水产养殖节能减排的对策。     

鱼、虾、蟹养殖池塘清塘排水水质及污染强度

为准确估计混养鱼、青虾、河蟹养殖池塘清塘时污染物的排放强度,实验选取三种类型池塘(混养鱼塘、青虾塘、河蟹塘)各5口。混养鱼塘清塘时一边捕捞一边用潜水泵排水;青虾塘在捕捞完成后即用潜水泵排水;河蟹塘在捕捞完成后1个月左右采用自流装置从表层开始排水并滞留30 cm水于塘内。采集三类池塘清塘前塘内水样及清塘过程中排水口水样,分析总氮、总磷、化学耗氧量和悬浮物等污染物浓度。分别以塘内水质和排水口水质的监测值估算了污染物的表观排放强度和实际排放强度。结果表明,随着塘内水位下降,混养鱼塘和青虾塘排水口的污染物浓度显著提高(P0.05)。混养鱼塘的实际污染强度显著高于其表观污染强度(P0.05)。然而河蟹池塘污染物的实际排放强度却显著低于表观排放强度(P0.05)。结果提示以塘内水质来估算池塘养殖污染物排放强度有明显误差;通过改进排水技术可以削减养殖污染排放量。