Risk evaluation of solar greenhouse cucumbers low temperature disaster based on GIS spatial analysis in Tianjin, China

References

• Arauz LF, Neufeld KN, Lloyd AL, Ojiambo PS. 2010. Quantitative models for germination and infection of Pseudoperonospora cubensis in response to temperature and duration of leaf wetness. Phytopathology. 100(9):959–967.
   Google Scholar
• Bennis N, Duplaix J, Enéa G, Haloua M, Youlal H. 2008. Greenhouse climate modelling and robust control. Comput Electron Agric. 61(2):96–107.
   Google Scholar
• Cai B, Liu S, Fei Y, Yang Z, Huang H. 2011. The risk grading regionalization of meteorological disaster of facilities agriculture in Jiangsu province. Chin Agric Sci Bull. 27(20):285–291.
   Google Scholar
• Canakci M, Yasemin Emekli N, Bilgin S, Caglayan N. 2013. Heating requirement and its costs in greenhouse structures: a case study for Mediterranean region of Turkey. Renew Sustain Energy Rev. 24:483–490.
   Google Scholar
• Carter DA. 1995. The scaled risk integral – a simple numerical representation of case societal risk for land use planning in the vicinity of major accident hazards, loss prevention in the process industries, Vol. 2, Amsterdam: Elsevier．
   Google Scholar
• Chen X. 2013. One hundred questions about key technology of cucumber production in greenhouse. China: Chemical Industry Publishing House; p. 45–46.
   Google Scholar
• Chen S, Li Z, Liu S. 2014. Review of facilities agriculture meteorological disasters and prospect of associated study methods. Chin Agric Sci Bull. 30(20):302–307.
   Google Scholar
• Colucci SJ. 2008. Host range, fungicide resistance and management of Pseudoperonospora cubensis, causal agent of cucurbit downy mildew. Raleigh, North Carolina: North Carolina State University. Master of Science.
   Google Scholar
• Denby B, Walker SE, Hor_Alek OJ, Eben PK. 2005. Interpolation and assimilation methods for European scale air quality assessment and mapping. Part I: review and recommendations. Spain: European Topic Centre. (Technical Report).
   Google Scholar
• Hengl T. 2009. A practical guide to geostatistical mapping. Amsterdam: University of Amsterdam; p. 1–270.
   Google Scholar
• Huang C, Yang Z, Liu H, Pei D, Zhu K, Zhou Z. 2012. Risk analysis and regionalization of wind hazard to sunlight greenhouse in Beijing. J Nat Dis. 21(3):43–49.
   Google Scholar
• Li T. 2013. Theory and practice on vegetable cultivation in solar greenhouse. China: China Agriculture Press; p. 163–174.
   Google Scholar
• Ling Y, Wang F. 2009. Cultivation technology of cucumbers in solar greenhouse. Hebei, Shijiazhuang, China: Hebei Science and Technology Publishing House; p. 12–16.
   Google Scholar
• Liu S, Xue QY, Li Z, Li C, Gong Z, Li N. 2015. An air temperature predict model based on BP Neural networks for solar greenhouse in North China. J Chin Agric Univ. 20(1):176–184.
   Google Scholar
• Li Z, Wang T, Gong Z, Li N. 2013. Forewarning technology and application for monitoring low temperature disaster in solar greenhouses based on internet of things. Transactions of the Chinese society of agricultural engineering. Vol. 29, Beijing, China: Ingenta; p. 229–236.
   Google Scholar
• Pang M, Qiao L. 2011. Disaster prevention and reduction technology of greenhouse vegetables, Hebei, Shijiazhuang, China: Hebei Science and Technology Press; p. 54–55.
   Google Scholar
• Piers M. 1998. Methods and models for the assessment of third party risk due to aircraft accidents in the vicinity of airports and their implications for societal risk[C]. In: Jorissen RE, Stallen PJM, editors. Quantified societal risk and policy making．Dordrecht, Netherlands: Kluwer Academic Publishers．
   Google Scholar
• Sethi VP, Sharma SK. 2008. Survey and evaluation of heating technologies for world wide agricultural greenhouse applications. Solar Energy. 82(9):832–859.
   Google Scholar
• Shetty NV, Wehner TC, Thomas CE, Doruchowski RW, Vasanth Shetty KP. 2002. Evidence for downy mildew races in cucumber tested in Asia, Europe, and North America. Sci Hort. 94(3–4):231–239.
   Google Scholar
• Stansly PA, Sánchez PA, Rodrı́guez JM, Cañizares F, Nieto A, Leyva MJL, Fajardo M, Suárez V, Urbaneja A. 2004. Prospects for biological control of Bemisia tabaci (Homoptera, Aleyrodidae) in greenhouse tomatoes of southern Spain. Crop Protect. 23(8):701–712.
   Google Scholar
• Sun L. 2012. Greenhouse meteorology and crop protection research. Shenyang, China: Liaoning Science and Technology Publishing House; p. 7–9.
   Google Scholar
• Wang J. 2010. Modern agricultural meteorology service. Beijing, China: China Meteorological Press; p. 264–291.
   Google Scholar
• Wei R, Zhao C. 2005. Confirmation of most suitable area for developing fruit and vegetable solar greenhouse house in Hebei province by using GIS technology. Chin J Agric Resour Regional Plann. 26(1):35–38.
   Google Scholar
• Yağcıoğlu A. 2005. Greenhouse mechanization. İzmir, Turkey: Ege University, Faculty of Agriculture.
   Google Scholar
• Yang Z, Fei Y, Zhu J, Huang H, Zhang J. 2012. Spatiotemporal distribution features of sparse sunlight disaster of facility agriculture in Jiangsu Province. J Northeast Agric Univ. 43(2):64–69.
   Google Scholar
• Yu H. 2012. The research on the disaster of low temperature and spare sunlight of vegetables seeding in Greenhouse - tomato and cucumber for example. Shenyang, China: Shenyang Agricultural University; p. 1–49.
   Google Scholar