羅國芝,女,1974年4月生,湖北襄樊人,漢族,2000年畢業上海水產大學,獲農學碩士學位;2007年7月畢業於同濟大學,獲工學博士學位。教授,博士生導師。
基本介紹
- 中文名:羅國芝
- 國籍:中國
- 民族:漢
- 出生日期:1974年4月
- 畢業院校:上海水產大學
- 職業:教師
- 性別:女
人物經歷,教育背景,工作背景,教學工作,科教項目,發表論文,授權專利,獲獎情況,
羅國芝,女,上海海洋大學水產與生命學院教授,博士生導師。
主要研究方向:水產養殖用水重複利用;循環水養殖系統;水產養殖規劃和環境管理。主要研究成果:循環水工廠化淡水魚類養殖系統關鍵技術研究與開發 ( 成果號 9312006Y0360) 。在《水產學報》、《中國水產科學》、《農業環境科學學報》等核心期刊上發表論文 30 余篇。申請或授厚酷府權發明專利 4 項。獲 2005 年上海海洋大學科技獎一等獎、國家發改委 2006 中國國際工業博覽會最具技術交易潛力一等獎、上海市寒多 2006 年度科學技術獎一等獎,校科技獎一等獎。
2003-2007,環境科學,博士學位
1997-2000,水產養殖,碩士學位
2017/01-2018/01,美國內部拉斯加州立大學奧馬哈分校,生物系,訪問學者。
2005/09-2016/12,上海海洋大學,水產與生命學院,副教授
2002/09-2003/09,上海水產大學,漁業學院,講師
2000/07-2002/09,上海水產大學,漁業學院,助教
本科生課程:《集約化水產養殖水環境控制》,《水產養殖工程》,《環境保護與可持續發展》
研究生笑擊應課程:《循環水工廠化養殖系統》,《水產養殖水環境監測與調控》
留學生課程:《Recirculating Aquaculture System》《Water Chemistry in Aquaculture》
[1]上海市科委地方院校能力建設項目:淺水跑道式循環淡水養殖系統最佳化與效果示範,主持。
[2]國家自然科學基金項目:水產養殖系統中生物絮凝介導氨氮轉化關鍵因素的研究,主持。
[3]上海市科委工企試姜程中心台棕店能力提升項目:上海水產養殖工程技術研究中心,參加。
[4]國家科技支撐計畫項目子課題:鰻魚工廠化高效養殖技術集成研究與系統構建,參加。
[5]上海市教委創新項目:利用可生物降解頸戲您鑽聚合物作碳源和載體進行水產養殖用水異養反硝化機理的初步研究,主持。
[6]公益性行業(農業)科研專舉棗套愉項子課題:養殖節能裝備關鍵技術研究與套用,參加。
(第一作者或通訊作者,2012-至今)
[1]Luo G.Z*, Zhang N, Cai S.L, Tan H.X, Liu Z.F,2017. Nitrogen dynamics, bacterial community composition and biofloc quality in biofloc-based systems culturedOreochromis niloticuswith poly-β-hydroxybutyric and polycaprolactone as external carbohydrates. Aquaculture 479: 732-741.
[2]Luo G.Z*, Li W.Q,Tan H.X, Chen X.Q, 2017. Comparing salinities of 0, 10 and 20 in biofloc genetically improved farmed tilapia (Oreochromis niloticus) production systems. Aquaculture and Fisheries 2:220-226.
[3]Guozhi Luo�6�5,Nan Zhang, Hongxin Tan,Zhiwei Hou, Wenchang Liu, 2017. Efficiency of producing bioflocs with aquaculture waste by using poly--hydroxybutyric acid as a carbon source in suspended growth bioreactors. Aquacultural Engineering 76:36-40.
[4]Nan Zhang,Guozhi Luo*,Hongxin Tan, Wenchang Liu, Zhiwei Hou, 2016. Growth, digestive enzyme activity and welfare of tilapia (Oreochromis niloticus) reared in a biofloc-based system with poly-β-hydroxybutyric as acarbon source. Aquaculture 264:710-717.
[5]Guozhi Luo*,Guimei Xu, Hongxin Tan,Jinfang Gao, Wenchang Liu, 2016.Effect of dissolved oxygen on denitrification using polycaprolactone as both the organic carbon source and the biofilm carrier.International Biodeterioration & Biodegradation 110:155-162.
[6]Guozhi Luo*,Guimei Xu, Jinfang Gao,Hongxin Tan, 2016. Effect of dissolved oxygen on nitrate removal using polycaprolactone as an organic carbon source and biofilm carrier in fixed-film denitrifying reactors. Journal of Environmental Science 43:147-152.
[7]G. Luo*,M.Yao, H.Tan, W. Wu, 2016.The performance of microbial flocs produced with aquaculture waste as food forArtemia.Aquaculture Nutrition DOI: 10.1111/anu.12519.
[8]Guozhi Luo*,Jiao Wang, Niannian Ma, Zefeng Liu, Hongxin Tan, 2016. Effects of Inoculated Bacillus subtilis on Geosmin and 2-Methylisoborneol Removal in Suspended Growth Reactors Using Aquacultural Waste for Biofloc Production. Journal Microbiology Biotechnology 26: 1–8
[9]Niannian Ma,Guozhi Luo*,Hongxin Tan, Li Li, Xiaoyong Wang, 2015. Removal of Geosmin and 2-Methylisoborneol by Bioflocs Produced with Aquaculture Waste. Aquaculture International DOI 10.1007/s10499-015-9929-0
[10]Guozhi Luo, Qi Gao, ChaohuiWang,Wenchang Liu, Dachuan Sun, Li Li, Hongxin Tan*, 2014. Growth, digestive activity, welfare, and partial cost-effectiveness of genetically improved farmed tilapia(Oreochromis niloticus)cultured in a recirculating aquaculture system and an indoor biofloc system, Aquaculture 42:1-7.
[11]Wenyan LIANG,Guozhi LUO*,Hongxin TAN,Niannian MA,Nan ZHANG, Li LI, 2014. Efficiency of biofloc technology in suspended growth reactors treating aquacultural solid under intermittent Aeration. Aquacultural Engineering 59:41-47.
[12]Guozhi Luo*,Wenyan Liang,Hongxin Tan,Chen Yao,Nan Zhang,Lu Lu, 2013. Effects of calcium and magnesium addition on the start-up of sequencing batch reactor using biofloc technology treating solid aquaculture waste. Aquacultural Engineering 57: 32-37.
[13]Chen Yao,Hong-Xin Tan,Guo-Zhi Luo*,Li Li, 2013. Effects of Temperature on Inorganic Nitrogen Dynamics in Sequencing Batch Reactors using Biofloc Technology to Treat Aquaculture Sludge,North American Journal of Aquaculture 75:463-467.
[14]Luo Guozhi,Yoram Avnimelech,Yun-feng Pan,Hong-xin Tan*, 2013. Inorganic nitrogen dynamics in sequencing batch reactors using biofloc technology to treat aquaculture sludge.Aquacultural Engineering 52:73-79.
[15]Guo-zhi Luo*,Ping Li, Hong-xin Tan,Jun Du,Wen-yan Liang, 2013. The start-upand saline adaptation of mesophilic anaerobic sequencing batch reactor treating sludge from recirculating aquaculture systems. Aquacultural Engineering 54:9-15.
[16]Guozhi Luo,Li Li, Qian Liu, Guimei Xu, Hongxin Tan*, 2014. Effect of dissolved oxygen on heterotrophic denitrification using poly(butylene succinate) as the carbon source and biofilm carrier. Bioresource Technology 17:152-158.
[17]Guozhi Luo*,Gang Liu ,Hong-xin Tan,2013. Effects of stocking density and food deprivation-related stress on the physiology and growth in adult Scortum barcoo(McCulloch & Waite).Aquaculture Research 44:885-894.
[18]Lu Lu,Hongxin Tan,Guozhi Luo*,Wenyan Liang, 2012. The effects ofBacillus subtilison nitrogen recycling from aquaculture solid waste using heterotrophic nitrogen assimilation in sequencing batch reactors. BioresourceTechnology 124:180-185.
[19]Luo Guozhi*,Na Zhang,Hongxin Tan, 2012. Effect of Low Salinity on Jade PerchScortum barcooPerformance in a Recirculating Aquaculture System. North American Journal of Aquaculture 74(3):395-399.
[20]Guozhi LUO,Wenjing SUN, Qian LIU, Yu HU, Hongxin TAN*, 2014. Effects of Nitrate Concentration on Heterotrophic Denitrification in Wastewater Using Poly(butylene succinate) as a Carbon Source and Carrier, Applied Mechanics and Materials 665: 469-478.
[21]劉倩,徐桂梅,羅國芝*,2016.水力停留時間對養殖污水固相反硝化處理效果的影響研究.漁業現代化42(06):6-10.
[22]高錦芳,譚洪新,顧德平,羅國芝*,陳家捷,劉文暢, 2016.利用好氧顆粒污泥處理水產循環養殖廢水的研究.環境污染與防治38(01):47-52,57
[23]羅國芝*,姚妙蘭,魯璐,姜瑞,吳萬浩,譚洪新, 2015.利用循環水養殖固體廢棄物進行鹵蟲幼體營養強化的效果研究.上海海洋大學學報24(3): 350-356
[24]王潮輝,高啟,譚洪新,劉文暢,羅國芝*, 2015.生物絮凝系統構建過程對吉富羅非魚免疫酶和生長的影響.中國水產科學22(4): 707-715
[25]馬念念,羅國芝*,譚洪新,姚秒蘭,王曉用,2015.枯草芽孢桿菌對土臭素和二甲基異冰片的降解動力學.環境科學36(4):240-245.
[26]羅國芝,董明來,劉倩,鄧棚文,譚洪新*,2013.以聚丁酸丁二醇酯為碳源去除含鹽水體硝酸鹽的研究.環境污染與防治35(3): 20-25,30.
發明專利(第1發明人)
[1]一種循環水養殖系統,ZL2010102319013,第1發明人。
[2]利用生物絮凝體懸浮液孵化鹵蟲的方法,ZL1025103540290,第1發明人。
[3]一種水產養殖用水氮素的去除方法,ZL2013101107139,第1發明人。
[4]一種跑道式生物絮凝養蝦方式,ZL201410090584.6,第1發明人。
[5]一種水產養殖用水氮素的去除方法,ZL2013101107139,第1發明人。
[6]利用生物絮凝體懸浮液孵化鹵蟲的方法, ZL2012103540290,第1發明人。
[7]一種去除封閉式水產養殖水體中土腥味的方法, ZL2013102508292,第1發明人。
[8]一種封閉式水產養殖苗種培育系統, ZL2014100905846,第1發明人。
[1]上海市科技一等獎,循環水工廠化淡水魚類養殖系統關鍵技術研究與開發,排名第4。
[2]2006年中國國際工業博覽會“最具技術交易潛力獎”一等獎,高密度循環水工廠化水產養殖系統,國家發改委頒發的,排名第2。
[3]金橋獎一等獎,循環水工廠化養殖系統工藝設計與套用研究獎,排名第2。
[2]Luo G.Z*, Li W.Q,Tan H.X, Chen X.Q, 2017. Comparing salinities of 0, 10 and 20 in biofloc genetically improved farmed tilapia (Oreochromis niloticus) production systems. Aquaculture and Fisheries 2:220-226.
[3]Guozhi Luo�6�5,Nan Zhang, Hongxin Tan,Zhiwei Hou, Wenchang Liu, 2017. Efficiency of producing bioflocs with aquaculture waste by using poly--hydroxybutyric acid as a carbon source in suspended growth bioreactors. Aquacultural Engineering 76:36-40.
[4]Nan Zhang,Guozhi Luo*,Hongxin Tan, Wenchang Liu, Zhiwei Hou, 2016. Growth, digestive enzyme activity and welfare of tilapia (Oreochromis niloticus) reared in a biofloc-based system with poly-β-hydroxybutyric as acarbon source. Aquaculture 264:710-717.
[5]Guozhi Luo*,Guimei Xu, Hongxin Tan,Jinfang Gao, Wenchang Liu, 2016.Effect of dissolved oxygen on denitrification using polycaprolactone as both the organic carbon source and the biofilm carrier.International Biodeterioration & Biodegradation 110:155-162.
[6]Guozhi Luo*,Guimei Xu, Jinfang Gao,Hongxin Tan, 2016. Effect of dissolved oxygen on nitrate removal using polycaprolactone as an organic carbon source and biofilm carrier in fixed-film denitrifying reactors. Journal of Environmental Science 43:147-152.
[7]G. Luo*,M.Yao, H.Tan, W. Wu, 2016.The performance of microbial flocs produced with aquaculture waste as food forArtemia.Aquaculture Nutrition DOI: 10.1111/anu.12519.
[8]Guozhi Luo*,Jiao Wang, Niannian Ma, Zefeng Liu, Hongxin Tan, 2016. Effects of Inoculated Bacillus subtilis on Geosmin and 2-Methylisoborneol Removal in Suspended Growth Reactors Using Aquacultural Waste for Biofloc Production. Journal Microbiology Biotechnology 26: 1–8
[9]Niannian Ma,Guozhi Luo*,Hongxin Tan, Li Li, Xiaoyong Wang, 2015. Removal of Geosmin and 2-Methylisoborneol by Bioflocs Produced with Aquaculture Waste. Aquaculture International DOI 10.1007/s10499-015-9929-0
[10]Guozhi Luo, Qi Gao, ChaohuiWang,Wenchang Liu, Dachuan Sun, Li Li, Hongxin Tan*, 2014. Growth, digestive activity, welfare, and partial cost-effectiveness of genetically improved farmed tilapia(Oreochromis niloticus)cultured in a recirculating aquaculture system and an indoor biofloc system, Aquaculture 42:1-7.
[11]Wenyan LIANG,Guozhi LUO*,Hongxin TAN,Niannian MA,Nan ZHANG, Li LI, 2014. Efficiency of biofloc technology in suspended growth reactors treating aquacultural solid under intermittent Aeration. Aquacultural Engineering 59:41-47.
[12]Guozhi Luo*,Wenyan Liang,Hongxin Tan,Chen Yao,Nan Zhang,Lu Lu, 2013. Effects of calcium and magnesium addition on the start-up of sequencing batch reactor using biofloc technology treating solid aquaculture waste. Aquacultural Engineering 57: 32-37.
[13]Chen Yao,Hong-Xin Tan,Guo-Zhi Luo*,Li Li, 2013. Effects of Temperature on Inorganic Nitrogen Dynamics in Sequencing Batch Reactors using Biofloc Technology to Treat Aquaculture Sludge,North American Journal of Aquaculture 75:463-467.
[14]Luo Guozhi,Yoram Avnimelech,Yun-feng Pan,Hong-xin Tan*, 2013. Inorganic nitrogen dynamics in sequencing batch reactors using biofloc technology to treat aquaculture sludge.Aquacultural Engineering 52:73-79.
[15]Guo-zhi Luo*,Ping Li, Hong-xin Tan,Jun Du,Wen-yan Liang, 2013. The start-upand saline adaptation of mesophilic anaerobic sequencing batch reactor treating sludge from recirculating aquaculture systems. Aquacultural Engineering 54:9-15.
[16]Guozhi Luo,Li Li, Qian Liu, Guimei Xu, Hongxin Tan*, 2014. Effect of dissolved oxygen on heterotrophic denitrification using poly(butylene succinate) as the carbon source and biofilm carrier. Bioresource Technology 17:152-158.
[17]Guozhi Luo*,Gang Liu ,Hong-xin Tan,2013. Effects of stocking density and food deprivation-related stress on the physiology and growth in adult Scortum barcoo(McCulloch & Waite).Aquaculture Research 44:885-894.
[18]Lu Lu,Hongxin Tan,Guozhi Luo*,Wenyan Liang, 2012. The effects ofBacillus subtilison nitrogen recycling from aquaculture solid waste using heterotrophic nitrogen assimilation in sequencing batch reactors. BioresourceTechnology 124:180-185.
[19]Luo Guozhi*,Na Zhang,Hongxin Tan, 2012. Effect of Low Salinity on Jade PerchScortum barcooPerformance in a Recirculating Aquaculture System. North American Journal of Aquaculture 74(3):395-399.
[20]Guozhi LUO,Wenjing SUN, Qian LIU, Yu HU, Hongxin TAN*, 2014. Effects of Nitrate Concentration on Heterotrophic Denitrification in Wastewater Using Poly(butylene succinate) as a Carbon Source and Carrier, Applied Mechanics and Materials 665: 469-478.
[21]劉倩,徐桂梅,羅國芝*,2016.水力停留時間對養殖污水固相反硝化處理效果的影響研究.漁業現代化42(06):6-10.
[22]高錦芳,譚洪新,顧德平,羅國芝*,陳家捷,劉文暢, 2016.利用好氧顆粒污泥處理水產循環養殖廢水的研究.環境污染與防治38(01):47-52,57
[23]羅國芝*,姚妙蘭,魯璐,姜瑞,吳萬浩,譚洪新, 2015.利用循環水養殖固體廢棄物進行鹵蟲幼體營養強化的效果研究.上海海洋大學學報24(3): 350-356
[24]王潮輝,高啟,譚洪新,劉文暢,羅國芝*, 2015.生物絮凝系統構建過程對吉富羅非魚免疫酶和生長的影響.中國水產科學22(4): 707-715
[25]馬念念,羅國芝*,譚洪新,姚秒蘭,王曉用,2015.枯草芽孢桿菌對土臭素和二甲基異冰片的降解動力學.環境科學36(4):240-245.
[26]羅國芝,董明來,劉倩,鄧棚文,譚洪新*,2013.以聚丁酸丁二醇酯為碳源去除含鹽水體硝酸鹽的研究.環境污染與防治35(3): 20-25,30.
授權專利
發明專利(第1發明人)
[1]一種循環水養殖系統,ZL2010102319013,第1發明人。
[2]利用生物絮凝體懸浮液孵化鹵蟲的方法,ZL1025103540290,第1發明人。
[3]一種水產養殖用水氮素的去除方法,ZL2013101107139,第1發明人。
[4]一種跑道式生物絮凝養蝦方式,ZL201410090584.6,第1發明人。
[5]一種水產養殖用水氮素的去除方法,ZL2013101107139,第1發明人。
[6]利用生物絮凝體懸浮液孵化鹵蟲的方法, ZL2012103540290,第1發明人。
[7]一種去除封閉式水產養殖水體中土腥味的方法, ZL2013102508292,第1發明人。
[8]一種封閉式水產養殖苗種培育系統, ZL2014100905846,第1發明人。
獲獎情況
[1]上海市科技一等獎,循環水工廠化淡水魚類養殖系統關鍵技術研究與開發,排名第4。
[2]2006年中國國際工業博覽會“最具技術交易潛力獎”一等獎,高密度循環水工廠化水產養殖系統,國家發改委頒發的,排名第2。
[3]金橋獎一等獎,循環水工廠化養殖系統工藝設計與套用研究獎,排名第2。
