Sustainable Cities: Viability of a Hybrid Aeroponic/Nutrient Film Technique System for Cultivation of Tomatoes
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Sustainable Cities: Viability of a Hybrid Aeroponic/Nutrient Film Technique System for Cultivation of Tomatoes

Authors: D. Dannehl, Z. Taylor, J. Suhl, L. Miranda, R., Ulrichs, C., Salazar, E. Fitz-Rodriguez, I. Lopez-Cruz, A. Rojano-Aguilar, G. Navas-Gomez, U. Schmidt

Abstract:

Growing environmental and sustainability concerns have driven continual modernization of horticultural practices, especially for urban farming. Controlled environment and soilless production methods are increasing in popularity because of their efficient resource use and intensive cropping capabilities. However, some popular substrates used for hydroponic cultivation, particularly rock wool, represent a large environmental burden in regard to their manufacture and disposal. Substrate-less hydroponic systems are effective in producing short cropping cycle plants such as lettuce or herbs, but less information is available for the production of plants with larger root-systems and longer cropping times. Here, we investigated the viability of a hybrid aeroponic/nutrient film technique (AP/NFT) system for the cultivation of greenhouse tomatoes (Solanum lycopersicum ‘Panovy’). The plants grown in the AP/NFT system had a more compact phenotype, accumulated more Na+ and less P and S than the rock wool grown counterparts. Due to forced irrigation interruptions, we propose that the differences observed were cofounded by the differing severity of water-stress for plants with and without substrate. They may also be caused by a higher root zone temperature predominant in plants exposed to AP/NFT. However, leaf area, stem diameter, and number of trusses did not differ significantly. The same was found for leaf pigments and plant photosynthetic efficiency. Overall, the AP/NFT system appears to be viable for the production of greenhouse tomato, enabling the environment to be relieved by way of lessening rock wool usage.

Keywords: Aeroponic/nutrient film technique, greenhouse, nutrient dynamic, soilless culture, urban farming, waste reduction.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1131259

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References:


[1] United Nations World Urbanization Prospects: The 2014 Revision, Highlights (ST/ESA/SER.A/352); Department of Economic and Social Affairs, Population Division: 2014.
[2] P. A. Putra, H. Yuliando, "Soilless culture system to support water use efficiency and product quality: a review," in International Conference on Agro-Industry, vol. 3, Guritno, A. D., Schlich, E., Pawelzik, E., Eds. Elsevier B.V.: 2015, pp 283-288.
[3] A. Perrin, C. Basset-Mens, B. Gabrielle, "Life cycle assessment of vegetable products: a review focusing on cropping systems diversity and the estimation of field emissions," International Journal of Life Cycle Assessment, vol. 19, no. 6, pp. 1247-1263, 2014.
[4] A. Hussain, K. Iqbal, S. Aziem, P. Mahato, A. K. Negi, "A review on the science of growing crops without soil (soilless culture) – A novel alternative for growing crops," International Journal of Agriculture and Crop Sciences, vol. 7, no., pp. 833-842, 2014.
[5] FAO, "Good agricultural practices for greenhouse vegetable crops: Principles for Mediterranean climate areas," in FAO Plant Production and Protection Paper, vol. 217, Baudoin, W., Nono-Womdim, R., Lutaladio, N., Hodder, A., Castilla, N., Leonardi, C., De Pascale, S., Qaryouti, M., Duffy, R., Eds. Food and Agriculture Organization of the United Nations: Rome, Italy, 2013, pp 1-616.
[6] S. Thomaier, K. Specht, D. Henckel, A. Dierich, R. Siebert, U. B. Freisinger, M. Sawicka, "Farming in and on urban buildings: Present practice and specific novelties of Zero-Acreage Farming (ZFarming)," Renewable Agriculture and Food Systems, vol. 30, no. 1, pp. 43-54, 2015.
[7] D. Savvas, "Hydroponics: A modern technology supporting the application of integrated crop management in greenhouse," J. Food. Agric. Environ., vol. 1, no. 1, pp. 80-86, 2003.
[8] A. AlShrouf, " Hydroponics, aeroponic and aquaponic as compared with conventional farming," American Scientific Research Journal for Engineering, Technology and Sciences, vol. 27, no. 1, pp. 247-255, 2017.
[9] D. Dannehl, J. Suhl, C. Ulrichs, U. Schmidt, "Evaluation of substitutes for rock wool as growing substrate for hydroponic tomato production," J. Appl. Bot.-Angew. Bot., vol. 88, no., pp. 68-77, 2015.
[10] W. T. Bussell, S. Mckennie, "Rockwool in horticulture, and its importance and sustainable use in New Zealand," New. Zeal. J. Crop. Hort., vol. 32, no. 1, pp. 29-37, 2004.
[11] C. M. Olympios, "Soilless Media under protected cultivation Rockwool, Peat, Perlite and other Substrates," Acta Hort., vol. 323, no., pp. 215-232, 1992.
[12] A. Anton, M. Torrellas, J. I. Montero, "Environmental impact assessment of Dutch tomato crop production in a venlo glasshouse," Acta Hort., vol. 92, no., pp. 781-792, 2010.
[13] J. Pieters, B. Van Assche, A. Buekens, "Reducing solid waste streams specific to soilless horticulture," HortTechnology, vol. 8, no. 3, pp. 396-401, 1998.
[14] G. M. Dias, N. W. Ayer, S. Khosla, R. Van Acker, S. B. Young, S. Whitney, P. Hendricks, "Life cycle perspectives on the sustainability of Ontario greenhouse tomato production: Benchmarking and improvement opportunities," J. Clean. Prod., vol. 140, no., pp. 831-839, 2017.
[15] M. Raviv, "Substrate’s end-of-life: environmental and horticultural considerations," Acta Hort., vol. 1112, no., pp. 281-289, 2016.
[16] M. B. Jackson, P. S. Blackwell, J. R. Chrimes, T. V. Sims, "Poor aeration in NFT and a means for its improvement," J. Hort. Sci., vol. 59, no. 3, pp. 439-448, 1984.
[17] Y. Kawasaki, S. Matsuo, Y. Kanayama, K. Kanahama, "Effect of root-zone heating on root growth and activity, nutrient uptake, and fruit yield of tomato at low air temperatures," J. Japan. Soc. Hort. Sci., vol. 83, no. 4, pp. 295-301, 2014.
[18] I. Nir, "Growing plants in aeroponics growth system," Acta Horticulturae (Wageningen), vol. 126, no., pp. 435–448, 1982.
[19] M. Chiipanthenga, M. Maliro, P. Demo, J. Njoloma, "Potential of aeroponics system in the production of quality potato (Solanum tuberosum L.) seed in developing countries," African Journal of Biotechnology, vol. 11, no., pp. 3993-3999, 2012.
[20] E. Ritter, B. Angulo, P. Riga, C. Herran, J. Relloso, M. San Jose, "Comparison of hydroponic and aeroponic cultivation systems for the production of potato minitubers," Potato Research, vol. 44, no. 2, pp. 127-135, 2001.
[21] F. Göhler, H. D. Molitor, Erdelose Kulturverfahren im Gartenbau. Eugen Ulmer GmbH & Co.: Stuttgart, Germany, 2002.
[22] D. Dannehl, T. Rocksch, U. Schmidt, "Modelling to estimate the specific leaf area of tomato leaves (cv. Pannovy)," Acta Hort., vol. 1099, no., pp. 79-86, 2015.
[23] H. K. Lichtenthaler, A. Gitelson, M. Lang, "Non-destructive determination of chlorophyll content of leaves of a green and an aurea mutant of tobacco by reflectance measurements," J. Plant Physiol., vol. 148, no. 3-4, pp. 483-493, 1996.
[24] H. P. Klaring, M. Zude, "Sensing of tomato plant response to hypoxia in the root environment," Sci. Hortic., vol. 122, no. 1, pp. 17-25, 2009.
[25] J. Penuelas, F. Baret, I. Filella, "Semi-empirical indexes to assess carotenoids/chlorophyll a ratio from leaf spectral reflectance," Photosynthetica, vol. 31, no. 2, pp. 221-230, 1995.
[26] B. Genty, J. M. Briantais, N. R. Baker, "The relationship between the quantum yield of photosynthetic electron-transport and quenching of chlorophyll fluorescence," Biochim. Biophys. Acta, vol. 990, no. 1, pp. 87-92, 1989.
[27] DIN ISO 10694, "Soil quality - Determination of organic and total carbon after dry combustion (elementary analysis) (ISO 10694:1995)," vol., no., pp., 1996.
[28] DIN ISO 13878, "Soil quality - Determination of total nitrogen content by dry combustion ("elemental analysis") (ISO 13878:1998)," vol., no., pp., 1998.
[29] M. D. Gale, S. Youssefian, "Dwarfing genes in wheat," in Progress in plant breeding, vol. 1, Russell, G. E., Ed. Butterworths & Co.: London, 1985, pp 1-36.
[30] A. D. Mackay, S. A. Barber, "Effect of soil moisture and phosphate level on root hair growth of corn roots," Plant Soil, vol. 86, no. 3, pp. 321-331, 1985.
[31] M. Sakamoto, T. Suzuki, "Effect of rootzone temperature on growth and quality of hydroponically grown red leaf lettuce (Lactuca sativa L. cv. Red Wave)," Journal of Plant Sciences, vol. 6, no., pp. 2350-2360, 2015.
[32] F. N. Dalton, A. Maggio, G. Piccinni, "Effect of root temperature on plant response functions for tomato: comparison of static and dynamic salinity stress indices," Plant Soil, vol. 192, no., pp. 307-319, 1997.
[33] B. Bugbee, J. W. White, "Tomato growth as affected by root-zone temperature and the addition of gibberellic acid and kinetin to nutrient solutions," American Society for Horticultural Science, vol. 109, no., pp. 121-125, 1984.
[34] J. McDonald, T. Ericsson, C. M. Larsson, "Plant nutrition, dry matter gain and partitioning at the whole plant level," J. Exp. Bot., vol. 47, no., pp. 1245-1253, 1996.
[35] G. I. Ågren, O. Franklin, "Root: shoot ratios, optimization and nitrogen productivity," Ann. Bot., vol. 92, no. 6, pp. 795-800, 2003.
[36] A. Komosa, T. Kleiber, B. Markiewicz, "The effect of nutrient solutions on yield and macronutrient status of greenhouse tomato (Lycopersicon esculentum Mill.) grown in aeroponic and rockwool culture with or without recirculation of nutrient solution," Acta Scientiarum Polonorum-Hortorum Cultus, vol. 13, no. 2, pp. 163-177, 2014.
[37] M. Mozafariyan, K. Saghafi, A. E. Bayat, S. Bakhtiari, "The effects of different sodium chloride concentrations on the growth and photosynthesis parameters of tomato (Lycopersicum esculentum cv. Foria)," Intl. J. Agri. Crop. Sci., vol. 6, no. 4, pp. 203-207, 2013.
[38] M. Al Hassan, M. Martinez Fuertes, F. J. Ramos Sanchez, O. Vicente, M. Boscaiu, "Effects of salt and water stress on plant growth and on accumulation of osmolytes and antioxidant compounds in cherry tomato," Notulae Botanicae Horti Agrobotanici, vol. 43, no. 1, pp. 1-11, 2015.
[39] F. Brini, M. Hanin, I. Mezghani, G. A. Berkowitz, K. Masmoudi, "Overexpression of wheat Na+/H+ antiporter TNHX1 and H+-pyrophosphatase TVP1 improve salt- and drought-stress tolerance in Arabidopsis thaliana plants," J. Exp. Bot., vol. 58, no. 2, pp. 301-308, 2007.
[40] R. M. Rivero, T. C. Mestre, R. Mittler, F. Rubio, F. Garcia-Sanchez, V. Martinez, "The combined effect of salinity and heat reveals a specific physiological, biochemical and molecular response in tomato plants," Plant Cell Environ., vol. 37, no. 5, pp. 1059-1073, 2014.
[41] M. Mohammed, R. Shibli, M. Ajlouni, L. Nimri, "Tomato root and shoot responses to salt stress under different levels of phosphorous nutrition," Journal of Plant Nutrition and Soil Science, vol. 21, no., pp. 1667-1680, 2008.
[42] C. C. De Groot, L. Marcelis, R. Van Den Boogaard, H. Lambers, "Growth and dry-mass partitioning in tomato as affected by phosphorus nutrition and light," Plant, Cell and Environment, vol. 24, no., pp. 1309-1317, 2001.
[43] M. He, F. A. Dijkstra, "Drought effect on plant nitrogen and phosphorous: a meta-analysis," New Phytol., vol. 204, no., pp. 924-931, 2014.
[44] R. Nazar, N. Iqbal, A. Masood, S. Syeed, N. A. Khan, "Understanding the significance of sulphur in improving salinity tolerance in plants," Environ. Exp. Bot., vol. 70, no., pp. 80-87, 2010.
[45] K. Nahar, R. Gretzmacher, "Effect of water stress on nutrient uptake, yield and quality of tomato (Lycopersicon esculentum Mill.) under subtropical conditions," Bodenkultur, vol. 53, no. 1, pp. 45-51, 2002.
[46] E. Ogren, G. Oquist, "Effects of drought on photosynthesis, chlorophyll fluorescence and photoinhibition susceptibility in intact willow leaves " Planta, vol. 166, no., pp. 380-388 1985.
[47] R. Khavari-Nejad, Y. Mostofi, "Effects of NaCl on photosynthetic pigments, saccharides and chloroplast ultrastructure in leaves of tomato cultivars," Photosyntheitca vol. 35, no., pp. 151-154, 1998.
[48] M. Chaves, J. S. Perrira, J. Maroco, L. Rodrigues, C. P. P. Ricardo, M. Osorio, I. Carvalho, T. Faria, C. Pinheiro, "How plants cope with water stress in the field? Photosynthesis and growth," Ann. Bot., vol. 89, no., pp. 907-916, 2002.
[49] M. Ashraf, P. C. Harris, "Photosynthesis under stressful environments: An overview," Phtosynthetica, vol. 51, no., pp. 163-190, 2013.