Aquaponics a modern approach for integrated farming and wise utilization of components for sustainability of food security: A review

Shreejana K.C 1 , Ronika Thapa 2 , Ashish Lamsal 3 , Shirish Ghimire 4 , Kavita Kurunju 5 , Pradeep Shrestha 6

1   Institute of Agriculture and animal Science, Gokuleshwor College, Baitadi, NEPAL
2   Institute of Agriculture and animal Science, Gokuleshwor College, Baitadi, NEPAL
3   Institute of Agriculture and animal Science, Gokuleshwor College, Baitadi, NEPAL
4   Institute of Agriculture and animal Science, Gokuleshwor College, Baitadi, NEPAL
5   Himalayan College of Agriculture Science and Technology, PU, Kathmandu, NEPAL
6   Himalayan College of Agriculture Science and Technology, PU, Kathmandu, NEPAL

✉ Coressponding author: See PDF.

doi https://doi.org/10.26832/24566632.2022.0701017

doi

Abstract

Aquaponics is the sustainable approaches of present day’s world for raising fish species along with vegetables in a symbiotic association for sustainable food production. People are facing food crisis not only because of the adverse environmental condition but also due to unbalance environment population ratio. That is the main reason why the entire world is more concerned about the production of more food for security and sustainability. Present day’s modern farming system mainly focus on the productivity increasing technology and in due course individual are utilizing more chemical compounds that result in the degradation of soil. It shows great impact on ecological environment. Most of the cultivable land is also turned out as a site of construction which reduces the cultivable land on earth and ultimately arising the food insecurity. In such a circumstance a new approach of aquaponics might be beneficial where water solely covers the two third of the total mass. Aquaponics is a soilless culture which gained immense popularity as it focuses on organic production of vegetables within a single recirculating aquaponics system. Along with the sustainability it also emphasis economic efficacy and enhancement of productivity.  It can be grown used on non-arable lands such as deserts, degraded soil or salty, sandy islands. So, it can integrate livelihood strategies to secure food and small incomes for landless and poor households.

Keywords:

Aquaponics, Food security, Soilless culture, Sustainability, Tilapia

Downloads

Download data is not yet available.

References

Acharya, B. S., Bhandari, M., Bandini, F., Pizarro, A., Perks, M., Joshi, D. R., & Sharma, S. (2021). Unmanned aerial vehicles in hydrology and water management–applications, challenges and perspectives. Water Resources Research, e2021WR029925.

Asael, Greenfeld, Ni rBecker, Janet F.Bornman, Sabrina Spatari, Dror Angela, L. (2021). Monetizing environmental impact of integrated aquaponic farming compared to separate systems. Science of The Total Environment, 792, 148459.

Bernstein, S. (2011). Aquaponic gardening: A step-by-step guide to raisingvegetable and fish together.

Bohl, M. (1977). Some initial aquaculture experiments in recirculating water systems. Aquaculture 11, 323-328.

Collins, M., Gratzek, J., Shotts, E. Jr, Dawe, D., Campbell, L.M., & Senn, D. (1975). Nitrification in an aquatic recirculating system. Journal of Fish Research Board, 32, 2025-2031.

Edwards, P. (2015). Aquaculture environment interactions: past, present and likely future trends Aquaculture Research for the Next 40 ears of Sustainable Global Aquaculture. 447, 2-14.

Endut, A., Jusoh, A., & Ali, N. (2014). Nitrogen budget and effluent nitrogen components in Aquaponics recirculation system. Desalin. Water Treatment 52, 744-752.

Endut, A., Jusoh, A., Ali, N., Wan Nik, W. B., Hassan, A. (2010). A study on the optimal hydraulic loading rate and plant ratios in recirculation aquaponic system. Bioresource Technology 101, 1511-1517.

Engle, C. R. (2015). Economics of Aquaponics. SRAC Publisher. Aquaculture Center.

FAO. (2014). The State of Food Insecurity in the World. Rome: IFAD and WEP , 1-57.

Heather, G.A.S. (2013). The earth transformed: an introduction to human impacts on the environment (John Wilet and Sons).

Krüner, G., & Rosenthal, H. (1983). Efficiency of nitrification in trickling filters using different substrates. Aquaculture Engineering, 2, 49-67.

Liang, J. Y., & Chien, Y. H. (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 85, 693-700.

Love, D. C., Fry, J. P., Genello, L., Hill, E. S, Frederick, J. A., Li, X., & Semmens, K. (2014). An international survey of aquaponics practitioners. PLoS ONE 9 (2).

Love, D. C., Fry, J. P., Li, X., Hill, E. S., Genello, L., Semmens, K., & Thompson, R. E. (2015). Commercial aquaponics production and profitability: findings from aninternational survey. Aquaculture, 435, 67-74.

Martins, C., Eding, E., Verdegem, M., & Heinsbroek, L. (2010). New developments in recirculating aquaculture systems in Europe:a perspective on environmental sustainability. Aquaculture Engineering, 43, 83-93.

Sneed, M.S., Allen, K., & Ellis, J. (1975). Fish farming and hydroponics. Aquaculture Fish Farmer, 2: 11-18.

Nichols, M.A., & Savidov, N.A. (2012). Aquaponics: A nutrient and water efficient production system. Acta Horticulture, 947, 129-132.

Pratt, C.W., & Cornely, K. (2014). Essential Biochemistry. 3rd edition. Edited by John Wiley and sons.

Rakocy, J. E., Shultz, R. C., Bailey, D. S., & Thoman, E. S. (2004). Aquaponic production of tilapia and basil:Comparing a batch and staggered cropping system. Acta Horticulture, 648, 63-69.

Resh, H. M. (2012). Hydroponic Food Production: A Definitive Guidebook for the Advanced Home Gardener and the Commercial Hydroponic Grower, (CRC Press).

Rizal, A., Dhahiyat, Y., Zahidah, Y., Andriani, A. A., Handaka & Sahidin, I.O.P. (2018). The economic and social benefits of an aquaponic system for the integrated production of fish and water plants. IOP Conference Series: Earth and Environmental Science, 137 012098.

Shah, K. K., Modi, B., Lamsal, B., Shrestha, J. & Aryal, S. P. (2021b). Bioactive compounds in tomato and their roles in disease prevention. Fundamental and Applied Agriculture 6(2), 210-224, https://doi.org/10.5455/faa.136276

Shah, K.K., Modi, B., Pandey, H.P., Subedi, A., Aryal, G., Pandey, M., & Shrestha, J. (2021a). Diversified Crop Rotation: An Approach for Sustainable agriculture production. Advances in Agriculture, e8924087. https://doi.org/10.1155/2021/8924087

Sharma, S., & Kreye, M. M. (2021). Public Attitudes towards Birds and Private Forest Land Conservation. Forests, 12(11), 1525.

Sommercille, C., Moti, C., Edoardo, P., Auston, S., & Alessandro, L. (2014). Small- scale aquaponic food production - integrated fish and plant farming FAO. (Italy: Fisheries and Aquaculture Technical Paper Rome) no. 589.

Timmons, M. B., Ebeling, J. M., Wheaton, F. W., Summerfelt, S. T., & Vinci, B. J. (2002). Recirculating Aquaculture System. Ithaca, New York: Cayuga Aqua Ventures.

Tyson, R.V., Simonne, E. H., Treadwell, D. D., White, J. M., & Simonne, A. (2008). Reconciling pH for ammonia biofiltration and cucumber yield in a recirculating aquaponic system with perlite biofilters. Horticulture Science, 43, 719-724.

Zou, Y., Hu, Z., Zhang, J., Xie, H., Guimbaud, C., & Fang, Y. (2016). Effects of pH onnitrogen transformations in media-based aquaponics. Bioresource Technology, 210, 81-87.

Published

2022-03-25

How to Cite

K.C, S. ., Thapa, R., Lamsal, A. ., Ghimire, S. ., Kurunju, K. ., & Shrestha, P. (2022). Aquaponics a modern approach for integrated farming and wise utilization of components for sustainability of food security: A review. Archives of Agriculture and Environmental Science, 7(1), 121-126. https://doi.org/10.26832/24566632.2022.0701017

Issue

Vol. 7 No. 1 (2022): March 2022 Issue

Section

Review Articles

Copyright (c) 2022 Agriculture and Environmental Science Academy

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.