高密度養殖蝦池間捕增產之研究

Shen-Chien Huang; 黃尚健

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/37799

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳弘成
dc.contributor.author	Shen-Chien Huang	en
dc.contributor.author	黃尚健	zh_TW
dc.date.accessioned	2021-06-13T15:44:25Z	-
dc.date.available	2013-07-09
dc.date.copyright	2008-07-09
dc.date.issued	2008
dc.date.submitted	2008-07-02
dc.identifier.citation	丁雲源、李武忠，1988。台灣地區養殖池常見之浮游生物圖鑑。農委會漁業特刊第十四號。丁雲源，1991。台灣西南部蝦池環境調查及改善。農委會漁業特刊。 28：133-134。丁雲源、李武忠，1991。海水蝦池常見之生物圖鑑。農委會漁業特刊第二十七號。于乃衡，2003。白蝦產業現況及展望。水產種苗協會-白蝦繁養殖手冊第七章。王克行，1998。蝦蟹類生物學。水產出版社-蝦蟹類增養殖學-第8、10章。吳瑋智，2006。砂蝦於魚蝦混養池的成長、不同蛋白質含量之商業飼料對其成長以及鹽度對其生理影響。國立台灣大學漁業科學所碩士論文。阮暐達，2006。斑節蝦養殖池之生態調查與其水質基準之研究。國立台灣大學漁業科學研究所碩士論文。徐節華，1998。輪捕輪放。江西水產科技，1998年第三期27-28頁。秦宗顯，1986。氨與亞硝酸對草蝦苗存活率之影響極其急性毒之研究。國立台灣海洋大學漁業研究所碩士論文。陳弘成、張銘昆、丘南威、徐嘉瑩，1989。宜蘭蝦池生態環境之研究。農委會漁業特刊No.16：277-298。陳弘成，1991。宜蘭蝦池環境調查及改善。農委會漁業特刊No.28：1-4。陳弘成、辛阿燕、高事宜，1991。宜蘭蝦池之生態與池蝦生長之研究。農委會漁業特刊No. 28：5-25。陳弘成，1992。成功的草蝦養殖法。農委會漁業特刊第三十一號。陳弘成，1994。蝦類養殖病害與管理。養魚世界，2，23-29。陳弘成，1996。高產量下蝦池生態與草蝦外型之研究。台大漁推8： 29-39。陳弘成，1997。極低鹽度養殖草蝦法之探討與改進。台大漁推9：1~7。陳弘成、張朝富、楊喜男、范姜文榮，1997。池蝦健康與蝦池環境之判定法。首屆世界華人蝦類養殖研討會，13頁。陳弘成、張朝富、楊喜男、范姜文榮，1998。池蝦健康與蝦池環境之判定法。第一屆世界華人蝦類養殖研討會。廈門。18頁。陳弘成，2000。病毒危害下蝦類養殖的精優管理之研究。中山大學學報39：11-15。陳弘成、高事宜、吳瑞梹、袁又宸，2001。斑節蝦養殖技術改進之研究。漁業署養殖特刊第四號水產養殖論文集(三)：1-9。陳弘成，2001。斑節蝦之精優養殖與新理念。養殖漁業，33:6-7。陳弘成，2004。提高帶原蝦苗育成效率之技術手冊。漁業署養殖特刊第八號，2-1~2-22。陳弘成，2003。白蝦的安全養殖及精優管理。水產種苗協會-白蝦繁養殖手冊第四章。陳弘成、吳雅琪、吳瑋智、高事宜，2006。第五屆世界華人蝦蟹養殖研討會論文集。陳建初，1981。水質分析。九大圖書公司：85-107。陳建初、涂智欽、楊文璽，1989。氨對斑節蝦蝦苗的急性毒性。臺灣水產學會誌 No.16(4)：261-270。陳建初、涂智欽，1990。亞硝酸對斑節蝦蝦苗的急性毒性。臺灣水產學會誌 No.17(4)：277-287。郭恩展，2006。氨對白蝦之毒性影響研究。國立台灣大學漁業科學研究所碩士論文。萬云輝，1997。輪捕輪放是養魚一項高產技術措施。農業養殖技術，1997年第七期12-13頁。廖一久，1969。蝦類養殖試驗。中國水產學會五十八年年會專題演講。蔡一心，蘇永全，1998。改進養殖環境，養好日本對蝦. 在蘇主編「蝦類的健康養殖」，50-55頁。海洋出版社，北京。鄭學淵，1992。外界氨濃度對斑節蝦血淋巴蛋白質、血藍素及酸鹼平衡之影響。國立海洋大學水產養殖研究所碩士論文。環檢所 (2000) 水中氨氮檢測方法－靛酚比色法。環署檢字第67626 號公告 NIEA W448.51B。環檢所 (2002) 水中亞硝酸鹽氮檢測方法－分光光度計法。環署檢字第0910083743A 號公告 NIEA W418.51C。環檢所 (2003) 中矽酸鹽檢測方法－鉬矽酸鹽比色法。環署檢字第 0920080856 號公告NIEA W450.50B。環檢所 (2000) 水中生化需氧量檢測方法。環署檢字第67626 號公告 NIEA W510.54B。環檢所 (2005) 水中正磷酸鹽之流動注入分析法－比色法。環署檢字第 0940034033A 號公告 NIEA W443.51C。蘇信彰，2001。台南縣北部砂蝦養殖池之生態研究。國立台灣海洋大學水產養殖所碩士論文。 Allen, P.G., Botsford, L.W., Schurr, A.M., Johnston, W.E., 1984. Bioeconomics of Aquaculture. New York, NY: Elsevier Science Publishers. Allan, G.L., Maguire, G.B., Hopkins, S.J., 1990. Acute and chronictoxicity of ammonia to juvenile Metapenaeus macleayi and Penaeus monodon and the influence of low dissolved-oxygen levels. Aquaculture 91: 265-280. Arnold, S., Sellars, M., Crocos, P., Coman, G., 2006. An evaluation of stocking density on the intensive production of juvenile brown tiger shrimp (Penaeus esculentus). Aquaculture 256, 174–179. Bower, C.E. and Bidwell, J.P., 1978. Ionization of ammonia in seawater: effects of temperature, pH, and salinity. J. Fish. Res. Board. Can. 35, 1012-1016. Boyd, C.E., 1982 Water quality management for pond fish culture. Elsevier. New York.pp.313. Boyd, C.E., 1989 Water quality management and aeration in shrimp farming. American Soybean Association and US Wheat Associates, Singapore: 70. Boyd, C.E., 1990. Water Quality in Ponds for Aquaculture. Birmingham Publishing, Birmingham, AL: 482 Briggs M.R.P. and Funge-Smith S.J. 1994. A nutrient budget of some intensive marine ponds in Thailand. Aquacult. Fish. Manage. 24:789-811. Brown, D.A. and D.J.Mcleay., 1975. Effect of nitrite on methemoglobin and tatal hemoglobin of juvenile rainbow trout. Prog. Fish Cult. 37(1)：36-38 Brummett, R.E., 2002. Comparison of African Tilapia Partial Harvesting Systems. Aquaculture 214:103–14. Chamberlain, G.W., 1997. Sustainability of world shrimp farming. In Global Trends: Fisheries Management (Pikitch E.K., Juppert D.D., Sissenwine M.P.). American Fisheries Society Symposium 20, Bethesda, Md. Charmantier, G., Charmantier-Daures, M., Bouaricha, N., Thuet, P., Aiken, D.E., Trilles, J.P., 1988. Ontogeny of osmoregulation and salinity tolerance in two decapod crustaceans: Homarus americanus and Penaeus japonicus. The Biological Bulletin175: 102-110. Chen, H.C., 1980. Feasibility study of a prawn/fish farming project in Indonesia. Taiwan Fisheries Consul. Inc.,pp.37 Chen, H.C., 1984. Water quality criteria for farming the grass shrimp, Penaeus monodon. Proceedings of the first international conference on the culture of penaeid prawns/shrimps, pp. 165 Chen, H. C. 2002. Better pond management for successful shrimp culture under the stress of viral diseases. 23 pages. Present in Shrimp Disease Management. June. At Nellore. India. Chen J. C., Liu P. C., Lei S. C., 1990. Toxicities of ammonia and nitrite to Penaeus monodon adolescents. Aquaculture 89: 127-137. Chen J. C. and F. H. Nan, 1991. Lethal effect of nitrite to Metapenaeus ensis larvae J. World Aquac. Soc. 22：51-56. Chen, J.C. and Lin, C.Y., 1992. Oxygen consumption and ammonia-N excretion of Penaeus chinensis juveniles exposed to ambient ammonia at different salinity levels. Comp. Biochem. Physiol., 102C, 287-291. Chen, J.C. and Nan, F.H., 1992. Effect of ambient ammonia on ammonia-N excretion and ATPase activity of Penaeus chinensis. Aquatic Toxicology, 23, 1-10. Chen, J.C. and Kou, Y.Z., 1993. Accumulation of ammonia in the hemolymph of Penaeus monodon exposed to ambient ammonia. Aquaculture, 109, 177-185. Cheng, C.S. and Chen, L.C., 1990. Growth characteristics and relationships among body length, body weight and tail weight of Penaeus monodon from a culture environment in Taiwan. Aquaculture 91, 253–263. Cheng, S.Y. and Chen, J.C., 1999. Hemocyanin oxygen affinity, and the fractionation of oxyhemocyanin and deoxyhemocyanin for Penaeus monodon exposed to elevated nitrite. Aquat. Toxicol., 45, 35-46. Colt, J.E. and Armstrong, D.A., 1981. Nitrogen toxicity to crustaceans, fish and molluscs. In: Allen L.J., Kinney E.C. (Eds.), Proceedings of the Bio-Engineering Symposium for Fish Culture. Fish Culture Section. American Fisheries Society, Northeast Society of Conservation Engineers, Bethesda, MD, pp. 34–47. Dall, W., 1981. Osmoregulatory ability and juvenile habitat preference in some penaeid prawns. Journal of Experimental Marine Biology and Ecology 54: 55-64. Davis, D.A. and Arnold, C.R., 1998. The design, management and production of a recirculating raceway system for the production of marine shrimp. Aquacultural Engineering 17, 193–211. Eddy, F.B. and Williams, E.M., 1987. Nitrite and fresh water fish. Chem. Ecol. 3: 1-38. EIFAC (European Inland Fisheries Advisory Commission), 1983. Water quality criteria for European freshwater fish. Water Res., 7, 1011-1022. Flegel, T.W., 1996. The while spot virus crisis in Asian shrimp culture. Aquaculture Asia: 9-32. Flegel, T. W., 1999. Emerging shrimp diseases and innovations to prevent their sperad. Fourth Symposium on Disease in Asian Aquaculture. Philippines. OP18. Fromm, P.O. and Gillette, J.R., 1968. Effect of ambient ammonia on blood ammonia and nitrogen excretion of rainbow trout (Salmo Gairdneri). Comp. Biochem. Physiol., 26, 887-896. Gabriela, P., Fabian, C., Adolfo, S., Carlos, R., 2001. Density and water exchange-dependent growth and survival of Litopenaeus setiferus postlarvae. Journal of the World Aquaculture Society 32, 167–176. Greenaway, P., 1991. Nitrogenous excretion in aquatic and terrestrial crustaceans. Mem. Queensl. Mus., 31, 215-227. Haines, T.A., 1981. Acidic precipition and its consequences for aquatic ecosystems: a review. Trans. Am. Fish. Soc. 110 (6): 669-707. Hannesson, R., 1986. Optimal thinning of a year-class with density-dependent growth. Canadian Journal of Fisheries and Aquatic Sciences 43, 889–892. Hanson, T.R., Lawrence, A., Posadas, B.C., 2006. Economics of partial harvesting in super-intensive recirculating shrimp production systems. In: Abstracts of Aquaculture America 2006, Las Vegas, Nevada. Hartenstein, R., 1970. Nitrogen metabolism in non-insect arthropods. In: J.W. Cambell(Editor), Comparative Biochemistry Of Nitrogen Metabolism, Vol. 1. Academic Press, New York, NY, pp. 299-372. Heath, A.G., 1995. Water pollution and fish physiology. Boca Raton: Lewis Publishers. Hopkins, J.S., Sandifer, P.A., Browdy, C.L., 1994. Sludge management in intensive pond culture of shrimp: effect of management regime on water quality, sludge characteristics, nitrogen extinction, and shrimp production. Aquacultural Engineering 13: 11-30. Jackson, C.J. and Wang, Y.G., 1998. Modelling growth rate of Penaeus monodon Fabricius in intensively managed ponds: effectsof temperature, pond age and stocking density. Aquaculture Research 29: 27–36. Kir, M., kumlu, M., Eroldogan, O.T., 2004. Effects of temperature on acute toxicity of ammonia to Penaeus semisulcatus juveniles. Aquaculture, 241, 479-489 Kinne, O., 1976. Cultivation of marine organisms: water quality management of technology. In: O. Kinne(Editor), Marine Ecology, Vol. 3, part 1. Wiley Interscience, New York, NY, pp. 79-300. Krom, M.D. and Neori, A., 1989. A total nutrient budget for an experimental intensive fish pond with circulatory moving seawater. Aquaculture, 88: 345-358. Liao P.B. and Mayo R.D., 1974. Intensified fish culture combining water reconditioning with pollution abatement. Aquaculture 3: 61-85 Liao, I.C. and Mural, T., 1986. Effect of dissolved oxygen, temperature and salinity on the oxygen consumption of the grass shrimp, Penaeus monodon, pp641-646. In J.L. Maclean, L.B. Daton and L.V. Hosillos (Eds.).The First Asian Fisheries Forum, Asian Fisheries Society, Manila, Philippines. Liao, I.C., 1989. Penaeus monodon culture in Taiwan: through two decades of growth. Int. J. Aquat. Fish. Technol. 1: 16-24. Lightner D.V. and Redman R.M., 1998. Shrimp disease and current diagnosis methods. Aquaculture 164: 201–220. Liao I.C. and Chien, Y.H., 1994. Culture of Kuruma prawn (Penaeus japonicus Bate) in Asia. Special Report, World Aquaculture 25 (1):8–33 Losordo, T.M., Masser, M.P., Rakocy, J., 1992. Recirculating aquaculture tank production systems. A overview of critical conservations. Southern Regional Aquaculture Centre Publication no: 45. Stoneville, MS, pp. 6. Macarty P.L. and Haung, R.T., 1971. Nitrogen removal from wastewaters by biological nitrification and detrification. In：Sykes G. and F. A. Skinner(eds.). Microbiological spects of pollution, London, Academic press P215-232. Martin J.L., VeranY., Guelorget O., Pham D.,1998. Shrimp rearing: stocking density, growth, impact on sediment, waste output and their relationships studied through the nitrogen budget in rearing ponds. Aquaculture 164: 135-149. Masser, M.P., Rakocy, J., Losordo, T.M., 1992. Recirculating aquaculture tank production systems. A overview of critical conservations. Southern Regional Aquaculture Center Publication no: 45. Stoneville, MS, pp. 12. Monfort, P., Kosenko, E., Erceg, S., Canales, J.J., Felipo, V., 2002. Molecular mechanism of acute ammonia toxicity: role of NMDA receptors. Neurochem. Int., 41, 95-102. Morgan D.O. and McMahon B.R., 1982. Acid tolerance and effects of sublethal acid exposure on iono-regulation and acid–base status in two crayfish Procambarus clarki and Orconectes rusticus. J. Exp. Biol. 97: 214–252. Moss, S.M., Otoshi, C.A., Leung, P.S., 2005. Optimizing strategies for growing larger L. vannamei. Global Aquaculture Advocate 8, 68–69. Motoh, H., 1985. Biology and ecology Penaeus monodon. Proceedings of the first international conference on the culture of penaeid prawns/shrimps, pp. 27-36 Murray, C.A. and Zeibell, C.D., 1984. Acclimation of rainbow trout to high pH to prevent stocking mortality in summer. Prog. Fish Cult. 46:176–179. Muthuvan, V., 1991. Nutrient budget and water quality in intensive marine shrimp culture ponds. AIT master thesis AE: 91-40. Noor, H.S., Fortes, R.D., Parado, E.F., 1994. Effect of pH and ammonia on survival and growth of the early stages of Penaeus monodon Fabricius. Aquaculture 125: 67–72. Ostrensky, A. and Wasielesky, W., 1995. Acute toxicity of ammonia to various life stages of the Sao Paulo shrimp, Penaeus paulensis Pérez-Farfante, 1967. Aquaculture, 132, 339-347. Parry, G., 1960. Excretion. In: T.H. Waterman(Editor), The Physiology of Crustacea, Vol. 1. Academic Press, New York, NY, pp. 341-366. Piyatiratitivorakul, S., Rengpipat, S., Viyakarn, V., Nitithamayong, C., Menasveta, P., Mita, T., Maruyama, M., 2001. High efficient closed recirculating tube-system use for Penaeus monodon culture.6th Asian Fish Forum: 198. Randall, D.J. and Tsui, T.K.N., 2002. Ammonia toxicity in fish. Mar. Pollut. Bull., 45, 17-23. Ray,W.M. and Chien, Y.H., 1992. Effects of stocking density and aged sediment on tiger prawn, Penaeus monodon, nursery system. Aquaculture 104: 231-248. Regnault, M., 1987. Nitrogen excretion in marine and fresh-water crustacea. Biol. Rev. 62: 1-24. Rodriguez, M.G., 1999. Calculus of the biochemical oxygen demand of effluents with xenobiotics, Journal Environmental Science and Health, A34(4): 879–897. Russo, R.C., 1985. Ammonia, nitrite, and nitrate. In: Fundamentals of aquatic toxicology: methods and applications (Ed. by Rand, G.M., Petrocelli, S.R.), pp. 455-471. Washington: Hemisphere Publishing Corporation. Spaargaren, G. and Van Vliet B.J.M., 1998. Lifestyles, consumption and the environment: the ecological modernization of domestic consumption. Strickland, J.D. and Parsons, T.R., 1972. A practical handbook of seawater analysis. Fish. Res. Bd. Canada Bulletin. 167: 310. Teichert-Coddington, D.R., Rodriguez, R., Toyofuku, W., 1994. Cause of cyclic variation in Honduras shrimp production. World Aquaculture 25: 57–61. Thongrak, S., Prato, T., Chiayvareesajja, S., Kurtz, W., 1997. Economic and water quality evaluation of intensive shrimp production systems in Thailand. Agricultural Systems 53: 121–141. Thurston, R.V., 1980. Some factor affecting the toxicity of ammonia to fishes. EPA Ecol. Res. Ser., EPA-600/9-80-034, pp. 118-137. Tseng, K.F., Su, H.M., Su, M.S., 1998. Culture of Penaeus monodon in a recirculating system. Aquacultural Engineering 17: 138-147. Wickins, J.F., 1976. The tolerance of warm-water prawns to recirculated water. Aquaculture 9: 19-37. Wickins, J.F., and T.W. Beard., 1978. Prawn culture research. MAFF. Lab. Leaf.,no.42,pp.13-14. Wright, P.A., 1995. Nitrogen excretion: three end products, many physiological roles. J. Exp. Biol., 198, 273-281. Wyban, J.A., Lee, C.S., Sato, V.T., Sweeney, J.N., Richards, J.W.K., 1987. Effect of stocking density on shrimp growth rates in manure-fertilized ponds. Aquaculture 61, 23–32. Yu, J.P. and Hirayama, K., 1986. The effect of un-ionized ammonia on the growth of the rotifer in mass culture. Bull. Jpn. Soc. Sci. Fish, 52, 1509-1513 Yu, R., Leung, P.S., 2006. Optimal partial harvesting schedule for aquaculture. Marine Resource Economics 21, 301–315. Yu, R., Leung, P.S., Bienfang, P., 2007. Modeling partial harvesting in intensive shrimp culture: A network-flow approach. European Journal of Operational Research, doi:10.1016/j.ejor.2007.10.031
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/37799	-
dc.description.abstract	在超高密度的池蝦養殖中，於中後期常因蝦池的現存量(Biomass)太高、蝦體的排泄、飼料的殘餌與腐敗導致水質劇變管理困難。其影響輕微者使蝦類生長緩慢、池蝦大小參差不齊、蝦病叢生、浪費飼料；而嚴重者甚至於發生部份池蝦死亡或全池死亡殆盡，功虧一簣，此種情形在多種病毒的爆發肆虐下尤為明顯。因此在本研究，引入現存量、生產載量的養蝦管理理論，並採行間捕的管理技術，以期能易化養蝦困境，增加池蝦產量，並提高經濟效益。結果發現蝦池的水質環境與生產載量隨著養殖日期的增加，而有水質逐漸變差與蝦池最適生產載量的減少。其中特別是氨態氮的增加、溶氧量的降低與生長緩慢最為明顯。斑節蝦A池高密度養殖4個月的生長與間捕，使每公頃的產量達28公噸，池蝦大小為18-24公克。斑節蝦B池3個月的生長與間捕，使1公頃的產量達10公噸，池蝦大小為7-10公克。草蝦A池養殖由於水溫高，生長快速，二個月已長到50尾/斤(12公克) ，由於池釣蝦價太好，40尾/斤(15公克) 每公斤500元，故開始間捕出售15公克者，其總產量為每公頃7.13噸，由間捕的操作，每公頃增產1.65公噸，且體型亦大些、價格高些。管理者除了增加換水量、多加水車使用量或施用藥劑或活菌酵素淨化水質外，間捕可維護蝦池的生產載量(carrying capacity)，減少養蝦風險，增加蝦池的生產量與經濟效益，水質亦較易維持與穩定，池蝦存活率提高。間捕後能使小個體的池蝦快速成長達上市規格。間捕雖會增加人工及網具支出，但相較之下仍值得，故間捕為目前最具效果的健康安全與提高產量的管理方式之ㄧ。	zh_TW
dc.description.abstract	In shrimp ponds with highly intensive stocking density, at the middle and/or latter period, the high existing volume (biomass) of shrimp ponds, the excretion of shrimps, over-feeding and feed-corruption led to drastic changes in water quality. The slight effects are slow growing rate of shrimps, shrimp size differences, shrimp diseases and feed wasting. In some serious cases, the shrimps die partially or even completely. Therefore, in this study, the shrimp-farming management for existing capacity and high production, partial harvesting, were carried out in order to simplify the management of shrimp-farming, to increase production and to improve economic efficiency. The results showed that as the shrimp farming period passed by, the water quality and carrying capacity got worse gradually. In Kuruma shrimp (Penaeus japonicus) pond A, after four months the harvest per hectare increased to 28 tons, due to partial harvest, with the average body-size of 18-24 grams. Similarly in Kuruma shrimp pond B, the harvest per hectare was 10 tons, and the average body-size of shrimp was 7-10 grams after three months. Due to high temperature during the farming period, the growing rate of grass shrimp(P. monodon) pond A was very quickly, and after two months the total output was 7.13 tons per hectare. Because of the operation of partial harvesting, the output increased 1.65 tons per hectare, the shrimp body enlarged and the price increased. In addition to increase the water exchanging rate and application of biotics or water purification, the partial harvesting could maintain the production loading (carrying capacity), reduce farming risk, increase the output and benefits, simplify water quality management, increase the survival rate of shrimps and raise the growing rate of shrimps. Although the partial harvesting will increase the cost of farming, it is still worthy. Thus, the partial harvesting is one of the most effective management strategies increasing shrimp production.	en
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dc.description.tableofcontents	頁次誌謝.................................................... i 中文摘要................................................ii 英文摘要...............................................iii 壹、前言.................................................1 一、蝦類養殖回顧.....................................1 二、台灣蝦類養殖回顧與現況...........................3 貳、文獻回顧.............................................7 一、水質環境因子.....................................7 二、對蝦的養成與水質................................15 三、間捕收成........................................16 參、材料與方法..........................................19 一、養殖池的水質調查................................19 二、飼料投餵前後水中溶氧、pH值與氨氮之變化.........21 三、間捕收成........................................23 肆、結果................................................24 一、養殖池的水質與浮游生物調查......................24 二、飼料投餵前後水中溶氧、pH值與氨氮之變化.........34 三、間捕收成........................................39 伍、討論................................................42 一、養殖池的水質與浮游生物調查......................42 二、飼料投餵前後水中溶氧、pH值與氨氮之變化.........49 三、間捕收成........................................51 陸、結論................................................53 參考文獻................................................54
dc.language.iso	zh-TW
dc.subject	間捕、高密度、現存量、生產載量、蝦池	zh_TW
dc.subject	partial harvest、intensive shrimp pond 、Biomass、carrying capacity	en
dc.title	高密度養殖蝦池間捕增產之研究	zh_TW
dc.title	Studies on the production enhancement of intensive shrimp pond by partial harvests	en
dc.type	Thesis
dc.date.schoolyear	96-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	丁雲源,廖文亮,熊文俊
dc.subject.keyword	間捕、高密度、現存量、生產載量、蝦池,	zh_TW
dc.subject.keyword	partial harvest、intensive shrimp pond 、Biomass、carrying capacity,	en
dc.relation.page	64
dc.rights.note	有償授權
dc.date.accepted	2008-07-03
dc.contributor.author-college	生命科學院	zh_TW
dc.contributor.author-dept	漁業科學研究所	zh_TW
顯示於系所單位：	漁業科學研究所

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