Effect of different modified clay on the removal and germination of <i>Ulva prolifera</i> microscopic propagules

Zhang Yue; Song Xiuxian; Li Jing; Cao Xihua; Yu Zhiming

doi:10.3969/j.issn.0253-4193.2016.08.010

Article Contents

Article Navigation > Haiyang Xuebao > 2016 > 38(8): 93-102

Zhang Yue, Song Xiuxian, Li Jing, Cao Xihua, Yu Zhiming. Effect of different modified clay on the removal and germination of Ulva prolifera microscopic propagules[J]. Haiyang Xuebao, 2016, 38(8): 93-102. doi: 10.3969/j.issn.0253-4193.2016.08.010

Citation:

Zhang Yue, Song Xiuxian, Li Jing, Cao Xihua, Yu Zhiming. Effect of different modified clay on the removal and germination of Ulva prolifera microscopic propagules[J]. Haiyang Xuebao, 2016, 38(8): 93-102. doi: 10.3969/j.issn.0253-4193.2016.08.010

Citation:

PDF( 4135 KB)

Effect of different modified clay on the removal and germination of Ulva prolifera microscopic propagules

doi: 10.3969/j.issn.0253-4193.2016.08.010

1.
Key Laboratory of Marine Ecology and Environmental Sciences, Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China;Laboratory of Marine Ecology and Environmental Science, Qingdao National Laboratory for Marine Science and Technology, Qingdao 266071, China;University of Chinese Academy of Sciences, Beijing 100049, China
2.
Key Laboratory of Marine Ecology and Environmental Sciences, Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China;Laboratory of Marine Ecology and Environmental Science, Qingdao National Laboratory for Marine Science and Technology, Qingdao 266071, China

Received Date: 2015-12-03
Rev Recd Date: 2016-02-24

Abstract

Abstract

Two kinds of inorganic modified clay with three modifier/clay ratios were compared on the effect of removal and germination of Ulva prolifera microscopic propagules. The results indicated that removal efficiency increased with the rising amount of modified clay and modifier. AS modified clay was more effective than PAC modified clay, under the same concentration and modifier/clay ratio. The removal efficiency of 1:5 PAC modified clay under 0.5 g/L was 62 percent while AS modified clay was up to 80 percent. According to the data calculated after removal experiment, relative germination rate of microscopic propagules in upper water column decreased with the increasing of modified clay and modifier. In total water column, the relative germination rate rose firstly then fell with the peak at 0.1 g/L of modifier. Microscopic propagules treated with 1:3 modified clay failed to germinate under the concentration of 1.0 g/L in both AS and PAC modified clay. In general, suitable concentration of modified clay can remove the Ulva prolifera microscopic propagules effectively and inhibit their germination successfully, which provides a new possible way for the prevention and control of green tide disasters.
- Ulva prolifera,
- microscopic propagules,
- modified clay,
- removal,
- germination

FullText(HTML)

References(27)

References

宋宁而,王琪. 日本的浒苔治理经验及其对我国的启示[J]. 海洋信息,2009(3):15-19. Song Ninger,Wang Qi. The management experience of Enteromorpha spp. outbreak in Japan and its enlightenment to China[J]. Marine Information,2009(3):15-19.

国家海洋局. 2013年海洋灾害公报[EB/OL]. http://www.coi.gov.cn/gongbao/zaihai/201403/t20140324_30692.html,2014-03-24. State Oceanic Administration. Marine disaster bulletin 2013[EB/OL]. http://www.coi.gov.cn/gongbao/zaihai/201403/t20140324_30692.html,2014-03-24.

乔方利,马德毅,朱明远,等. 2008年黄海浒苔爆发的基本状况与科学应对措施[J]. 海洋科学进展,2008,26(3):409-410. Qiao Fangli,Ma Deyi,Zhu Mingyuan,et al. The basic conditions and scientific countermeasures in the Yellow Sea for the outbreak of Ulva prolifera in 2008[J]. Advances in Marine Science,2008,26(3):409-410.

刘春兰. 青岛浒苔暴发因素的探讨及对策[J]. 安徽农业科学,2013,41(4):1695-1698. Liu Chunlan. Discussion on factors for outbreak of Enteromorpha in Qingdao and countermeasures[J]. Journal of Anhui Agricultural Sciences,2013,41(4):1695-1698.

Hoffmann A J,Santelices B. Banks of algal microscopic forms:hypotheses on their functioning and comparisons with seed banks[J]. Marine Ecology Progress Series,1991,79:185-194.

Liu Feng,Pang Shaojun,Zhao Xiaobo,et al. Quantitative,molecular and growth analyses of Ulva microscopic propagules in the coastal sediment of Jiangsu province where green tides initially occurred[J]. Marine Environmental Research,2012,74:56-63.

Lotze H K,Schramm W,Schories D,et al. Control of macroalgal blooms at early developmental stages:Pilayella littoralis versus Enteromorpha spp.[J]. Oecologia,1999,119(1):46-54.

刘湘庆. 黄海绿潮形成过程中漂浮绿藻及微观繁殖体时空分布研究[D]. 青岛:国家海洋局第一海洋研究所,2014. Liu Xiangqing. Distributions of floating green algae and micro-propagules in the formatting and developing processes in the Yellow Sea[D]. Qingdao:The First Institute of Oceanography,State Oceanic Administration,2014.

王晓坤,马家海,叶道才,等. 浒苔(Enteromorpha prolifera)生活史的初步研究[J]. 海洋通报,2007,26(5):112-116. Wang Xiaokun,Ma Jiahai,Ye Daocai,et al. Preliminary study on the life history of Enteromorpha prolifera[J]. Marine Science Bulletin,2007,26(5):112-116.

Gao Shan,Chen Xiaoyuan,Yi Qianqian,et al. A strategy for the proliferation of Ulva prolifera,main causative species of green tides,with formation of sporangia by fragmentation[J]. PLoS One,2010,5(1):e8571.

Lin Apeng,Shen Songdong,Wang Jianwei,et al. Reproduction Diversity of Enteromorpha prolifera[J]. Journal of Integrative Plant Biology,2008,50(5):622-629.

Huo Yuanzi,Liang Hua,Wu Hailong,et al. Abundance and distribution of Ulva microscopic propagules associated with a green tide in the southern coast of the Yellow Sea[J]. Harmful Algae,2014,39:357-364.

林勇新. 形态特征及藻源有机质对改性粘土絮凝有害藻华生物效率的影响[D]. 青岛:中国科学院海洋研究所,2013. Lin Yongxin. Influence of aggregates morphology and algal organic materials on the efficiency of modified clays deployed in mitigation of HAB organisms[D]. Qingdao:Institute of Oceanology, Chinese Academy of Sciences,2013.

李靖,孙雷,宋秀贤,等. 改性粘土对浒苔(Ulva prolifera)微观繁殖体去除效果及萌发的影响[J]. 海洋与湖沼,2015,46(2):345-350. Li Jing,Sun Lei,Song Xiuxian,et al. Removal of microscopic propagule and its germination of Ulva prolifera with modified clay[J]. Oceanologia et Limnologia Sinica,2015,46(2):345-350.

张晓红. 温度、盐度等环境因子对浒苔(Enteromorpha prolifera)及繁殖体生长的影响[D]. 青岛:国家海洋局第一海洋研究所,2011. Zhang Xiaohong. Preliminary study on temperature,salinity and other environmental factors effect the visible thalli and microscopic propagules of Enteromorpha prolifera[D]. Qingdao:The First Institute of Oceanography,State Oceanic Administration,2011.

俞志明,邹景忠,马锡年. 一种提高粘土矿物去除赤潮生物能力的新方法[J]. 海洋与湖沼,1994,25(2):226-232. Yu Zhiming,Zou Jingzhong,Ma Xinian. A new method to improve the capability of clays for removing red tide organisms[J]. Oceanologia et Limnologia Sinica,1994,25(2):226-232.

卢光远. 改性粘土治理藻华对主要营养元素循环及藻毒素的影响[D]. 青岛:中国科学院青岛海洋所,2014. Lu Guangyuan. Effects of HABs mitigation by modified clay on major nutrient cyclings and algal toxins[D]. Qingdao:Institute of Oceanology, Chinese Academy of Sciences,2014.

吴萍,俞志明,杨桂朋,等. 新型表面活性剂改性粘土去除赤潮藻研究[J]. 海洋与湖沼,2006,37(6):511-516. Wu Ping,Yu Zhiming,Yang Guipeng,et al. Remediation from harmful algae bloom with organo-clay processed surfactant[J]. Oceanologia et Limnologia Sinica,2006,37(6):511-516.

张雅琪,俞志明,宋秀贤,等. 改性黏土对褐潮生物种Aureococcus anophagefferens的去除研究[J]. 海洋学报,2013,35(3):197-203. Zhang Yaqi,Yu Zhiming,Song Xiuxian,et al. Study on removal of brown tide-Aureococcus anophagefferens by modified clay[J]. Haiyang Xuebao,2013,35(3):197-203.

俞志明,邹景忠,马锡年,等. 粘土矿物去除赤潮生物的动力学研究[J]. 海洋与湖沼,1995,26(1):1-6. Yu Zhiming,Zou Jingzhong,Ma Xinian,et al. Study on the kinetics of clays removing red tide organisms[J]. Oceanologia et Limnologia Sinica,1995,26(1):1-6.

曹西华. 有机改性粘土去除赤潮生物澄渺琶攎溹瓕—潶晛?睝栮攠慒璛?爭濽濑瑦獢?椋渔?牀攬氲愰琰椴漮渠?瑡潯?慘汩畨浵楡渮甠浓?瑵潤汩敥牳愠湯据攠?潥晣?睡桮敩慳瑭嬠?嵮???潥畴牨湯慤汯?潯晧?娠桯敦樠楯慲湧条?啯渭楣癬敡特猠楩瑮礠???杯牶楩据畧氠瑲略牤攠?慩湤摥??楲晧敡?卩捳業敳湛捄敝献???ので??????????????は??扏牣?孡??嵬??楹猬渠楃敨物楮敥湳??休????噭?匠慯武愠汓慣畩獥歮慣獥?嘬?‰吰栴攮?敢晲显敛挲琲?漠晎?慦氬疐涛椰測槚甜浞?潉渮?拌椥潻攖氎攟捿瓆犦槹揿慮泻?懔掴瓑椧瘟楿琺礶?潱曍?瑊桝攮??榧?亥椬琲攰氱氳漬瀳猷椨猸?漺戱琲田猶愭??椱??挠敌汩氠?浩敮浳扨牵愬湘敵?慊晵瑮整物???獙畡灯????獧畲灵???呴倠慡獬攮?楅湦桦楥扣楴瑳椠潯湦嬠?嵩??佯灧敥湮??楮晤攠?卨捯楳数湨捯敲獵?㈠はの????㈠????????扨牯?孯??嵮??慥湳楩汳漠癡?剤????歭敥汮畴湳搠?书???????晡映数捲瑯獬?潦晥?獡格漯物琾?瑊敝爮洠?慯湵摲?污潬渠杯?琠敆物浳?慥汲畩浥楳渠楯畦洠?獨瑩牮敡猬猲‰漱渳?瀳样漨琸漩猺礱渲琰栶攭猱椲猱?爮攼獢灲椾牛愲琳楝漠滞?愎測摬?牴攬瀢爳漮搠疘挟瓿楩盹敷?挭愻炁愥捻槐璄礸?椔湶?慊?甮渠楷挋攎汖沼甬氱愹爹‵本爲收攨渲?昺氲愰朸攭氲氱愴琮攠???楚??畭杩汮敧測慍?朠牘慩据楩污楮猬??楥??孡?嵧???捴瑵慤??祯摦爠潭捡桩楮洠楮捵慴?敩瑥??祳搠牡潤扳楯潲汰潴杩楯据愠???っ???び??????ち??????扊牝?嬠??嵥??汯慬敯獧獩潡渠???呌??????牧湩煡瘠楓獩瑮????吱根改‵琬漲砶椨挲椩琺礲‰漸昭′愱水甮洼楢湲椾畛洲?瑝漠?瑷睡潲?慺捥楮搭潁?瑬潥汮攠牓愠湌琬?条牴敩敪湥?慩汣朠慅攮嬠?嵵??坡慣瑥攠牡?剤攠獣敯慬牬捯桩?ㄠ??????????????????[J]. Chemical Reviews,1974,74(3):385-400.

卢光远,宋秀贤,俞志明,等. 改性黏土絮凝海洋原甲藻对水体中氮、磷的影响研究[J]. 中国环境科学,2014,34(2):492-498. Lu Guangyuan,Song Xiuxian,Yu Zhiming,et al. Effects of flocculation of Prorocentrum micans by modified clay on nitrogen and phosphorus[J]. China Environmental Science,2014,34(2):492-498.

Callow M E,Jennings A R,Brennan A B,et al. Microtopographic cues for settlement of zoospores of the green fouling alga Enteromorpha[J]. Biofouling,2002,18(3):229-236.

Park C S,Hwang E K. An investigation of the relationship between sediment particles size and the development of green algal mats (Ulva prolifera) on the intertidal flats of Muan,Korea[J]. Journal of Applied Phycology,2011,23(3):515-522.

D'antonio C M. Role of sand in the domination of hard substrata by the intertidal alga Rhodomela larix[J]. Marine Ecology Progress,1986,27(3):263-275.

Li Youxun,Zhang Xiaowen,Xu Dong,et al. Differential gene expression in Ulva prolifera under low light and low temperature conditions[J]. Current Genetics,2012,58(4):235-244.

林咸永,唐剑锋,李刚,等. 铝胁迫下小麦根细胞壁多糖组分含量的变化与其耐铝性的关系[J]. 浙江大学学报(农业与生命科学版),2005,31(6):724-730. Lin Xianyong,Tang Jianfeng,Li Gang,et al. Aluminum-induced change in cell-wall polysaccharide c

Relative Articles

Supplements(0)

Cited By

Proportional views