OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

海洋科学 2008

厦门筼筜湖龙须菜生长的主要影响因素

, PP. 47-51

郑新庆,姚雪芬,黄凌风,郭丰,林玉美,徐向伟,傅迅毅

Keywords: 龙须菜(Gracilaria,lemaneif,ormis),生长率,端足类摄食,水动力条件,筼筜湖

Full-Text Cite this paper Add to My Lib

Abstract:

通过在高度富营养化的海水泻湖----厦门筼筜湖开展龙须菜(Gracilarialemaneiformis)的延绳夹苗挂养与网笼挂养实验和室内端足类啃食海藻实验,探讨了影响筼筜湖龙须菜生长的主要因素。结果显示,筼筜湖龙须菜的表观生长率为0.42%/d,实际生长率为4.80%/d,强壮藻钩虾(Ampithoevalida)的摄食量占龙须菜总生长量的91.4%。而且,筼筜湖的水流缓慢,使藻体附着最高可达2.32g/gFW的颗粒物,明显抑制了龙须菜的生长。以上研究表明,端足类的啃食作用和不良的水动力条件是导致筼筜湖龙须菜表观生长率低的主要原因。

References

[1]	Dully J E. Amphipods on seaweeds: partners or pests? [J]. Oecologia, 1991, 83: 267-276.
[2]	Duffy J E, Hay M E. Strong impacts of grazing amphipods on the organization of a benthic community [J]. Ecol Monographs, 2000, 70(2): 237-263.
[3]	Tegner M J, Dayton P K. El Nino effects on southern California kelp forest communities[J].Adv Ecoll Res, 1987, 17: 243-279.
[4]	徐永健钱鲁闽.水动力条件对龙须菜N吸收的影响[J].海洋环境科学,2004,23(2):32.
[5]	Wheeler W N. Effect of boundary layer transport on the fixation of carbon by the giant kelp Macrocystis pyrifera [J]. Mar Bio, 1980, 56: 103-110.
[6]	McBane C D, Croker R A. Animal-algal relationships of the amphipod Hyale nilssoni (Rathke) in the rocky intertidal[J]. J Crust Biol, 1983, 3:592-601.
[7]	Geertz-Hansen O, Sand Jensen K A J, Hansen D F, et al. Growth and grazing control of abundance of the marine macroalga, Ulva lactuca L. in a eutrophic Danish estuary[J]. Aquatic Bot, 1993, 46:101-109.
[8]	欧寿铭潘荔卿魏育等.厦门员当湖纳潮排污能力研究[J].台湾海峡,2002,21(1):102-108.
[9]	徐永键钱鲁闽焦念志等.添加大型海藻龙须菜对中肋骨条藻赤潮的影响[J].,2005,24(4):533-539.
[10]	汤坤贤游秀萍林亚森等.龙须菜对富营养化海水的生物修复[J].生态学报,2005,25(11):3044-3051.
[11]	汤坤贤.龙须菜在网箱养殖区的生物修复研究[J].中国水产科学,2007,14(3):488-492.
[12]	胡海燕卢继武周毅等.龙须菜在鱼藻混养系统中的功能[A].中国科学院海洋研究所.海洋科学集刊(45)[C].北京:科学出版社,2005.169-175.
[13]	岳维忠黄小平黄良民谭烨辉殷健强.大型藻类净化养殖水体的初步研究[J].海洋环境科学,2004,23(1):13-16.
[14]	许忠能黄长江等.环境因子对细基江蓠繁枝变种氮、磷吸收速率的影响[J].应用生态学报,:.
[15]	钱鲁闽徐永健焦念志等.环境因子对龙须菜和菊花心江蓠的N、P吸收速率的影响[J].中国水产科学,2006,13(2):257-262.
[16]	刘静雯董双林.光照和温度对细基江蓠繁枝变型的生长和生化组成影响[J].青岛海洋大学学报,200131(3):332-338.
[17]	Balducci C, Sfriso A, Pavoni B. Macrofauna impact on Ulva rigida C. Ag. production and relationship with environmental variables in the lagoon ofVenice [J]. Mar Environ Res, 2001,52:7-49.
[18]	Brawley S H, Adey W H. The effect of micrograzers on algal community structure in a coral reef microcosm[J]. Mar Bio, 1981, 61:167-177.
[19]	Brawley S H, Fei X G. Studies of mesoherbivory in aquaria and in an unbarricaded marieulture farm on the Chinese coast[J]. J Phycol, 1987, 23: 614-623.
[20]	姬厚德潘伟然张国荣等.篑笃湖纳潮量与海水交换时间的计算[J].厦大学报,2006,45(5):660-663.
[21]	周时强柯才换谢小青等卢昌义谢小青.厦门贫笃湖大型底栖生物生态调查[A].卢昌义,谢小青.从贫笃港到贳笃湖[C].厦门:厦门大学出版社,2003.188-193.
[22]	Naldi M, Viaroli P. Nitrate uptake and storage in the seaweed Ulva rigida C. Agardh in relation to nitrate availability and thallus nitrate content in a eutrophic coastal lagoon (Sacea di Goro, Po River Delta, Italy) [J]. J Exp Mar Bio Eco, 2002, 269:65-83.
[23]	Peckol P, DeMeo-Anderson B, Rivers J, et al. Growth, nutrient uptake capacities and tissue constit- uents of the maeroalgae Cladophra vagabunda and Gracilaria tikvahiae related to site spicific nitrogen loading rates[J]. Mar Bio, 1994, 121: 175-185.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133