Skyfarming an ecological innovation to enhance global food security |
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Authors: | J?rn Germer Joachim Sauerborn Folkard Asch Jan de Boer Jürgen Schreiber Gerd Weber Joachim Müller |
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Affiliation: | (1) Institut f?r Pflanzenproduktion und Agrar?kologie in den Tropen und Subtropen, Universit?t Hohenheim, 70593 Stuttgart, Germany;(2) Fraunhofer-Institut f?r Bauphysik, 70569 Stuttgart, Germany;(3) Institut f?r Baustofflehre, Bauphysik, Technischen Ausbau und Entwerfen, Universit?t Stuttgart, 70174 Stuttgart, Germany;(4) Institut f?r Pflanzenz?chtung, Saatgutforschung und Populationsgenetik, Universit?t Hohenheim, 70593 Stuttgart, Germany;(5) Institut f?r Agrartechnik, Universit?t Hohenheim, 70593 Stuttgart, Germany |
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Abstract: | Population growth increases the demand for food and thus leads to expansion of cultivated land and intensification of agricultural production. There is a definite limit to both of these options for food security and their multiple negative effects on the environment undermine the aim for sustainability. Presently the impact of the Green Revolution on crop production is levelling off at high yields attained and even the potential of large scale irrigation programmes and transgenic crops seem to be limited in view of the expected increase in demand for food. Moreover, climate change threatens to affect agricultural production across the globe. Skyfarming represents a promising approach for food production that is largely environment independent and therefore immune to climate change. Optimal growing conditions, shielded from weather extremes and pests are aimed at raising plant production towards the physiological potential. Selecting rice as a pioneer crop for Skyfarming will not only provide a staple for a large part of the global population, but also significantly reduce the greenhouse gas emission caused by paddy cultivation. Multiplication of the benefits could be achieved by stacking production floors vertically. In Skyfarming the crop, with its requirements for optimal growth, development and production, determines the system’s design. Accordingly, the initial development must focus on the growing environment, lighting, temperature, humidity regulation and plant protection strategies as well as on the overall energy supply. For each of these areas potentially suitable technologies are presented and discussed. |
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