中国水产科学
中國水產科學
중국수산과학
Journal of Fishery Sciences of China
2014年
6期
1190-1199
,共10页
唐金玉%王岩%戴杨鑫%李由明
唐金玉%王巖%戴楊鑫%李由明
당금옥%왕암%대양흠%리유명
浮游植物%三角帆蚌%鱼类%综合养殖%配合饲料
浮遊植物%三角帆蚌%魚類%綜閤養殖%配閤飼料
부유식물%삼각범방%어류%종합양식%배합사료
phytoplankton%Hyriopsis cumingii%fish%integrated culture%formulated feed
利用三角帆蚌(Hyriopsis cumingii)、草鱼(Ctenoparyngodon idellus)、银鲫(Carassius gibelio)、鲢(Hypopthalmic-hthys molitrix)和鳙(Aristichthys nobilis)构建鱼蚌综合养殖系统,通过155 d围隔(面积32 m2)实验检验两种鱼类组合(草鱼+鲫+鲢+鳙或鲢+鳙)和两种饲喂方式(投喂或不投喂配合饲料)对浮游植物群落结构的影响。采用2×2设计,设4个处理: GISB-F(草鱼+鲫+鲢+鳙+投喂配合饲料)、GISB-NF(草鱼+鲫+鲢+鳙+不投喂配合饲料)、SB-F(鲢+鳙+投喂配合饲料)和SB-NF(鲢+鳙+不投喂配合饲料)。每个围隔内三角帆蚌、草鱼、鲫、鲢和鳙的放养量分别为20、15、5、5和5 ind。结果表明,各处理围隔内浮游植物生物量平均值为3.7×108~6.0×108 cell·L–1。改变鱼类组合和饲喂方式对浮游植物种类组成、优势种优势度、群落多样性、生物量以及浮游植物生物量中蓝藻的比例无显著影响,但投喂配合饲料导致叶绿素 a 增加。浮游植物实验前期主要优势种为十字藻属(Crucigenia)和栅藻属(Scenedesmus)种类,后期为平裂藻属(Merismopedia)和微囊藻属(Microcyslis)种类,表明浮游植物群落演变具有明显的季节性特点以及优势种逐渐演化为蓝藻的规律。水温、氨态氮、总氮和高锰酸钾指数对浮游植物群落结构具有显著影响。各处理围隔内氨态氮、总氮和高锰酸钾指数均随时间延长而增加,说明改变鱼类组合和饲喂方式不会影响围隔内蓝藻水华发生的趋势。
利用三角帆蚌(Hyriopsis cumingii)、草魚(Ctenoparyngodon idellus)、銀鯽(Carassius gibelio)、鰱(Hypopthalmic-hthys molitrix)和鳙(Aristichthys nobilis)構建魚蚌綜閤養殖繫統,通過155 d圍隔(麵積32 m2)實驗檢驗兩種魚類組閤(草魚+鯽+鰱+鳙或鰱+鳙)和兩種飼餵方式(投餵或不投餵配閤飼料)對浮遊植物群落結構的影響。採用2×2設計,設4箇處理: GISB-F(草魚+鯽+鰱+鳙+投餵配閤飼料)、GISB-NF(草魚+鯽+鰱+鳙+不投餵配閤飼料)、SB-F(鰱+鳙+投餵配閤飼料)和SB-NF(鰱+鳙+不投餵配閤飼料)。每箇圍隔內三角帆蚌、草魚、鯽、鰱和鳙的放養量分彆為20、15、5、5和5 ind。結果錶明,各處理圍隔內浮遊植物生物量平均值為3.7×108~6.0×108 cell·L–1。改變魚類組閤和飼餵方式對浮遊植物種類組成、優勢種優勢度、群落多樣性、生物量以及浮遊植物生物量中藍藻的比例無顯著影響,但投餵配閤飼料導緻葉綠素 a 增加。浮遊植物實驗前期主要優勢種為十字藻屬(Crucigenia)和柵藻屬(Scenedesmus)種類,後期為平裂藻屬(Merismopedia)和微囊藻屬(Microcyslis)種類,錶明浮遊植物群落縯變具有明顯的季節性特點以及優勢種逐漸縯化為藍藻的規律。水溫、氨態氮、總氮和高錳痠鉀指數對浮遊植物群落結構具有顯著影響。各處理圍隔內氨態氮、總氮和高錳痠鉀指數均隨時間延長而增加,說明改變魚類組閤和飼餵方式不會影響圍隔內藍藻水華髮生的趨勢。
이용삼각범방(Hyriopsis cumingii)、초어(Ctenoparyngodon idellus)、은즉(Carassius gibelio)、련(Hypopthalmic-hthys molitrix)화용(Aristichthys nobilis)구건어방종합양식계통,통과155 d위격(면적32 m2)실험검험량충어류조합(초어+즉+련+용혹련+용)화량충사위방식(투위혹불투위배합사료)대부유식물군락결구적영향。채용2×2설계,설4개처리: GISB-F(초어+즉+련+용+투위배합사료)、GISB-NF(초어+즉+련+용+불투위배합사료)、SB-F(련+용+투위배합사료)화SB-NF(련+용+불투위배합사료)。매개위격내삼각범방、초어、즉、련화용적방양량분별위20、15、5、5화5 ind。결과표명,각처리위격내부유식물생물량평균치위3.7×108~6.0×108 cell·L–1。개변어류조합화사위방식대부유식물충류조성、우세충우세도、군락다양성、생물량이급부유식물생물량중람조적비례무현저영향,단투위배합사료도치협록소 a 증가。부유식물실험전기주요우세충위십자조속(Crucigenia)화책조속(Scenedesmus)충류,후기위평렬조속(Merismopedia)화미낭조속(Microcyslis)충류,표명부유식물군락연변구유명현적계절성특점이급우세충축점연화위람조적규률。수온、안태담、총담화고맹산갑지수대부유식물군락결구구유현저영향。각처리위격내안태담、총담화고맹산갑지수균수시간연장이증가,설명개변어류조합화사위방식불회영향위격내람조수화발생적추세。
A 155-day enclosure experiment was conducted to evaluate the effects of co-cultured fish species combina-tion (either the combination of grass carp Ctenopharyngodon idellus, gibel carp Carassius gibelio, silver carp Hypoph-thalmichthys molitrix and bighead carp Aristichthys nobilis or the combination of silver carp and bighead carp) and formulated feed supplement regime (with or without feed supplement) on phytoplankton community in the enclosures with integrated culture of freshwater pearl mussel Hyriopsis cumingii and fishes. Four treatments, including stocking of grass carp, gibel carp, silver carp and bighead carp with formulated feed supplement (GISB-F ), stocking of grass carp, gibel carp, silver carp and bighead carp without formulated feed supplement (GISB-NF), stocking of silver carp and bighead carp with formulated feed supplement (SB-F), stocking of silver carp and bighead carp without formulated feed supplement (SB-NF), were examined. In each enclosure, 20 mussel, 15 grass carp, 5 gibel carp, 5 silver carp and 5 big-head carp were stocked, respectively. Results showed that the phytoplankton biomass ranged from 3.7 × 108 to 6.0 × 108 cell·L-1 during the experiment. No significant differences were found in the species composition, biomass and biodiver-sity index of phytoplankton, dominance index of the dominant species, and the ratio of cyanobacteria biomass to phy-toplankton biomass between enclosures GISB-F, GISB-NF, SB-F and SB-NF. However, the concentration of chloro-phyll a was higher in the enclosures fed formulated feed than in the enclosures without formulated feed supplement. Seasonal dynamics in phytoplankton community was observed. The dominant species of phytoplankton was green algae (Crucigenia and Scenedesmus) at the beginning of the experiment, and changed to blue-green algae (Merismopedia and Microcyslis) at the end of the experiment, suggesting the trend of occurrence of blue-green algae bloom. The factors that significantly influenced the alteration of community structure of phytoplankton included water temperature (T), ammonia (NH3-N), total nitrogen (TN) and chemical oxygen demand (CODMn). This result indicated that the changes of co-cultured species combination and formulated feed supplement could not change the trend that blue-green algal bloom finally occurred in the enclosures since NH3-N, TN and CODMn increased with the progress of the experiment.