THE DESIGN MODEL OF INTENSIVE VANAME SHRIMP PONDS FOR ECO-GREEN AQUACULTURE DEVELOPMENT IN THE AREA OF PROBOLINGGO, EAST JAVA, INDONESIA
DOI:
https://doi.org/10.32663/ja.v20i1.2582Keywords:
design model, eco-green aquaculture, ProbolinggoAbstract
Probolinggo, East Java, Indonesia, is an area with a high potential for shrimp aquaculture because these areas meet the criteria for candidate vaname shrimp aquaculture. Probolinggo in tropical regions with stable climate dan sea waves that have the potential for vaname shrimp aquaculture. The analysis required the following data: tidal data, topographic maps, network layouts, and water quality data for shrimp. This research was conducted by using the facilities at the brackish water and Marine Fisheries Laboratory of Probolinggo; an eco-green aquaculture circulation system was modeled and assessed using shrimp pond. First, the survey was located in Probolinggo City area, with coordinates 7° 44? 30.03? S and 113° 13? 58.68?. The methods used hydrological analysis: Water needs analysis for aquaculture irrigation based on the rules given by the Food and Agriculture Organization and water circulation analysis (Feedpedia, 2016). Material strength analysis of the embankments of the model pools: The comparison of area ratio toward embankment type dimension, design of dike and ponds, water filling discharge of brackish-water pond, and stages for ponds model design development. The results of the research suggested that dike should be planned to be as high as 1.5 m at the highest tide. The results of observations and tables of tidal recordings that had been verified then became the primary benchmark for planning the shrimp pond bottom. Based on the results of the analysis, it was found that the tidal height in the study location areas ranged from 2.5 to 3 m. A total of 80% of the area was used for production ponds.
References
Claude, E.B. (2003). Bottom soil and water quality management in shrimp ponds. J. Appl. Aquacult., 13(1), 11-33.
Cruz, C.R.D. (2014). Fishpond engineering: a technical manual for small and medium scale coastal fish farms in South East Asia. [cited 2018 Jan 15]. Retrieved from: http://www.fao.org/tempref/FI/CDrom/aquaculture/a0845t/volume2/docrep/field/003/e7171e/E7171E01.htm.
Feedpedia. (2016). Animal feed resources information system-INRA CIRAD FAO; [cited 2020 Feb 13]. Retrieved from: www.feedpedia.org.
Fidari, Jadfan, S., Maftuch, Bisri, M. (2017). Intensive Pool Design Model Planning Probolinggo District. 8(2017), 252-261. Retrieved from: https://www.jurnalpengairan.ub.ac.id/index.php/jtp/article/view/357.
Hein, Lars. (2000). Impact of shrimp farming on mangroves along India’s East Coast. Unasylva, 203(51), 48-55. Retrieved from: http://www.fao.org/tempref/docrep/fao/x8080e/x8080e08.pdf.
Joffrea, Olivier, M., Marijn, P., Klerkxc, L. (2018). Are shrimp farmers actual gamblers? An analysis of risk perception and risk management behaviors among shrimp farmers in the Mekong Delta. Aquaculture, 495, 528-537. Retrieved from: https://www.sciencedirect.com/science/article/pii/S0044848618301108.
Kyung, H.Y., Claude, E.B. (1994). Hydrology and water supply for pond aquaculture. New York: Springer Science Business Media Dordrecht.
Ling, C., James, S.D., Gregory, A.K., Qiuming, L. (2013). Life cycle assessment of Chinese shrimp farming systems targeted for export and domestic sales. Environ. Sci. Technol., 45(15), 6531-6538.
Low, S.J., Othman, H. (2017). Layout and Construction of Freshwater Fishponds In Malaysia. Retrieved from: http://www.fao.org/docrep/field/003/AC014E/AC014E04.htm.
Marianne, H. (2010). The environmental issue of fish farming in offshore water: perspectives, concerns, and research needs. Aquacult. Environ. Interact., 1, 57-70.
Ogbe, F.G., Takwa, K.T., Adegoye, M.S., Akoh, J.I. (2005). The hydrology of a small fish pond at the University of Agriculture. Benue State, Makurdi Experimental Fish Farm. In: 14th Annual Conference of the Fisheries Society of Nigeria (FISON). Ibadan, Nigeria, 103-107.
Sen Nag, Oishimaya. (2017). 10 Countries With The Longest Coastlines In Asia. WorldAtlas, Dec. 19. Retrieved from: worldatlas.com/articles/10-countries-with-the-longest-coastlines-in-asia.html.
Shunji, S., Derek, S., Simon, F.S. (2004). Status and potential of fisheries and aquaculture in Asia and the Pacific. Bangkok: Food and Agriculture Organization of the United Nations Regional Office for Asia and the Pacific.
Tides 4 Fishing. (2018). Progression of the tidal coefficient in January of 2018 [cited 2020 Feb 13]. Retrieved from: https://tides4fishing.com/tides/tidal-coefficient.
Varga, Monika, Csukasa, B., Kucskab, B. (2020). Implementation of an easily reconfigurable dynamic simulator for recirculating aquaculture systems. Aquacultural Engineering, 90(2020), 102073. Retrieved from: https://www.sciencedirect.com/science/article/pii/S0144860919302183
Viv, D.P., Engki, A.K. (2013). Prediction of sea-level rise impacts on the coastal areas of Surabaya using GIS. Int. J. Eng. Sci., 2(7), 1-9.
Downloads
Published
Issue
Section
License
Authors who publish with this journal agree to the following terms:
- Authors grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution 4.0 Internasional (CC BY 4.0) Licence that allows others to use and share the work with an acknowledgment of the work's authorship and initial publication in this journal.
- The author(s) still hold the copyright of his/her/their work and retain publishing rights without restrictions such as (but not limited to) patent right, lecture, book and reproduce the article for own purposes.
