Introduction 2 a developed world conservation paradigm 2


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The importance of agriculture in developing world(1)

References

Aredehey, G., Libsekal, H., Brhane, M., Welde, K. and Giday, A., 2018. Topsoil salinity mapping using geostatistical approach in the agricultural landscape of Timuga irrigation scheme, South Tigray, Ethiopia. Cogent Food & Agriculture4(1), p.1514959.

Brown, M., Ferguson, S.M. and Viju-Miljusevic, C., 2018. Intranational Trade Costs, Reallocation, and Technical Change: Evidence from a Canadian Agricultural Trade Policy Reform. In Agricultural productivity and producer behavior (pp. 125-155). University of Chicago Press.

Chandio, A.A., Yuansheng, J. and Magsi, H., 2016. Agricultural sub-sectors performance: an analysis of sector-wise share in agriculture GDP of Pakistan. International Journal of Economics and Finance8(2), pp.156-162.

Friedrich, T. and Kassam, A., 2016. Reasons to Adopt and Spread Conservation Agriculture Globally: a new paradigm for sustainable production intensification. In 2016 ASABE Annual International Meeting (p. 1). American Society of Agricultural and Biological Engineers.

Gosa, S.C., Lupo, Y. and Moshelion, M., 2019. Quantitative and comparative analysis of whole-plant performance for functional physiological traits phenotyping: New tools to support pre-breeding and plant stress physiology studies. Plant science282, pp.49-59.

Hatab, A.A., Cavinato, M.E.R., Lindemer, A. and Lagerkvist, C.J., 2019. Urban sprawl, food security and agricultural systems in developing countries: a systematic review of the literature. Cities94, pp.129-142.

Huang, J., Xu, C.C., Ridoutt, B.G., Wang, X.C. and Ren, P.A., 2017. Nitrogen and phosphorus losses and eutrophication potential associated with fertilizer application to cropland in China. Journal of Cleaner Production159, pp.171-179.

Jeunnette, M.N. and Hart, D.P., 2016, October. Remote sensing for developing world agriculture: Opportunities and areas for technical development. In Remote Sensing for Agriculture, Ecosystems, and Hydrology XVIII (Vol. 9998, p. 99980Y). International Society for Optics and Photonics.

Kamilaris, A. and Prenafeta-Boldú, F.X., 2018. Deep learning in agriculture: A survey. Computers and electronics in agriculture147, pp.70-90.

Ritter, W.F. and Rao Chitikela, S., 2020. The Mississippi River Basin Nitrogen Problem: Past History and Future Challenges to Solve It. In Watershed Management 2020 (pp. 109-123). Reston, VA: American Society of Civil Engineers.

Schroeder, K.G., Kobuta, I., Zimmermann, A., Krivonos, E., Ilina, D., Piatnytskyi, V., Akbarov, A., Durand, O. and Zorya, S., 2018. Uzbekistan-Agricultural Trade Policy Report (No. 132758, pp. 1-61). The World Bank.

Welle, P.D. and Mauter, M.S., 2017. High-resolution model for estimating the economic and policy implications of agricultural soil salinization in California. Environmental Research Letters12(9), p.094010.

Zahry, N.R. and Besley, J.C., 2019. Genetic engineering, genetic modification, or agricultural biotechnology: does the term matter?. Journal of Risk Research22(1), pp.16-31.

Zaller, J.G., 2020. Where Are the Solutions to the Pesticide Problem?. In Daily Poison (pp. 223-295). Springer, Cham.
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