El potencial de crecimiento en el sistema acuapónico de Lophantus Anisatus
Resumen
Los objetivos principales del documento son identificar un potencial de análisis de crecimiento en el sistema acuapónico de Lophantus Anisatus. Este modelo de sistema de producción integrado agrega más valor a los productos acuapónicos finales. El objetivo de este modelo es probar y predecir que las plantas de menta y el crecimiento de peces y las concentraciones netas de amonio y nitrato en el agua en un sistema acuapónico.
Descargas
##plugins.generic.paperbuzz.metrics##
Citas
Adler, Harper, Wade, Takeda & Summerfelt. (2000). Economic analysis of an aquaponic system for the integrated production of rainbow trout and plants. International Journal of Recirculating Aquaculture. 1(1): 15-34.
Bhatnagar & Devi. (2013). Water quality guidelines for the management of pond fish culture. International Journal of Environmental Science, 3: 6.
Boutwelluc, Juanita. (2007). “Aztecs’ aquaponics revamped”. Napa Valley Register.
Diver, Steve. (2006) “Aquaponics — integration of hydroponics with aquaculture” (PDF). ATTRA - National Sustainable Agriculture Information Service (National Center for Appropriate Technology). www.backyardaquaponics.com/guide-toaquaponics/fish
Francis-Floyd R, Watson, Petty & Pouder 2(009). Ammonia in aquatic systems (Univ. Florida, Dept. Fisheries Aquatic Sci., Florida Coop. Ext. Serv. FA-16), <http://edis.ifas.ufl.edu/FA031>. Date of Access 01 January, 2015.
Graber & Junge. (2009). Aquaponic Systems: Nutrient recycling from fish wastewater by vegetable production. Desalination, Volume 246, Issue 1:147-156.
Hoekstra & Chapagain. (2007). Water footprints of nations: water use by people as a function of their consumption pattern, Water Resources Management 21(1): 35–48.
Kibria & Haque. (2012). Integrated Multi-Trophic Aquaculture (IMTA) Systems in Freshwater Ponds in Bangladesh: Initial Understanding. Department of Aquaculture, Bangladesh Agricultural University, Mymensingh, Bangladesh.
Lal R, (2013). Beyond Intensification. In: Paper presentation at the ASA, CSSA, & SSSA international annual meetings, Tampa, Florida, USA.
Liang & Chien (2013). Effects of feeding frequency and photoperiod on water quality and crop production in a tilapia–water spinach raft aquaponics system. International Biodeterioration and Biodegradation, Volume 85: 693-700.
Mekonnen & Hoekstra. (2012). A global assessment of the water footprint of farm animal products. Ecosystems, 15(3), 401-415.
Mizanur, Yakupitiyage & Ranamukhaarachchi. (2004). Agricultural use of fish pond sediment for environmental amelioration. Thammasat International Journal of Science and Technology, 9(4):1-12.
Munteniță, Bria, Eni, Cîrciumaru & Graur. (2016). Physical characterization of nano-ferrites modified epoxy resins, Materiale Plastice, Vol. 53, nr. 3, pp. 509-511, ISSN 0025/5289, September.
Rakocy, Masser & Losordo. (2006). Recirculating aquaculture tank production systems: aquaponics-integrating fish and plant culture. SRAC , Volume 454: 1-16.
Rakocy. (1999). Aquaculture engineering – the status of aquaponics, part 1. Aquacult. Magaz, 25(4): 83-88.
Rogosa, Eli. (2013). “How does aquaponics work?”. Retrieved April 24
Salam, M.A., (2012) Raft Aquaponics for sustainable fish and vegetable production from high density fish pond. 5th Bi-annual Fisheries Conference and Research Fair 2012, Bangladesh Fisheries Research Forum, 18-19 January, 2012 at BARC, Dhaka.
Shoko, Limbu, Mrosso & Mgaya. (2014). A comparison of diurnal dynamics of water quality parameters in Nile tilapia (Oreochromis niloticus, Linnaeus, 1758) monoculture and polyculture with African sharp tooth catfish (Clarias gariepinus, Burchell, 1822) in earthen ponds. Aquaculture Research, 6: 1-13.
Toufique & Belton. (2014). Is Aquaculture Pro-Poor? Empirical Evidence of Impacts on Fish Consumption in Bangladesh, World Development, 64: 609-620.
Tyson,Treadwell & Simonne. (2011). Opportunities and challenges to sustainability in aquaponic systems. Horttechnology, Volume 21, Issue 1: 6-13.
