EDP Sciences logo
Web of Conferences logo
Search
Menu
All issues Volume 180 (2020) E3S Web Conf., 180 (2020) 03016 References
Open Access
Issue
E3S Web Conf.
Volume 180, 2020
9th International Conference on Thermal Equipments, Renewable Energy and Rural Development (TE-RE-RD 2020)
Article Number 03016
Number of page(s) 10
Section Rural Development
DOI https://doi.org/10.1051/e3sconf/202018003016
Published online 24 July 2020
  1. A. El Kenawy, J.I. Lopez-Moreno, S. M. Vicente-Serrano, Recent trends in daily temperature extremes over northeastern Spain (1960–2006), Nat. Hazards Earth Syst. Sci., 11, 21, (2011); [CrossRef] [Google Scholar]
  2. A. E. Croitoru, A. Piticar, Changes in daily extreme temperatures in the extra‐Carpathians regions of Romania, International Journal of Climatology, 33, 15, (2013); [CrossRef] [Google Scholar]
  3. Q. Wang, X. Fan, Z. Qin, M. Wang, Change trends of temperature and precipitation in the Loess Plateau Region of China, 1961–2010, Global and Planetary Change, 92–93, 10, (2012); [Google Scholar]
  4. A. R. Scorzini, M. Di Bacco,M. Leopardi, Recent trends in daily temperature extremes over the central Adriatic region of Italy in a Mediterranean climatic context, International Journal of Climatology, 38, (S1), 17, (2018); [CrossRef] [Google Scholar]
  5. E.B. Lupikasza, S. Hänsel, J. Matschullat, Regional and seasonal variability of extreme precipitation trends in southern Poland and central‐eastern Germany 1951–2006, International Journal of Climatology 31, 23, (2011); [CrossRef] [Google Scholar]
  6. C. Şulea-Iorgulescu, Researches on the development of an integrated computer system for monitoring the anti-hail rockets launch units, Universitaria Publishing House, Craiova, Romania, ISBN 978-606-14-0833-7 (2014); [Google Scholar]
  7. A. Piticar, PhD thesis Studies on recent climate change in Northeastern Romania, University “Babes-Bolyai” Cluj Napoca (2013); [Google Scholar]
  8. S. Mohr, M. Kunz, Recent trends and variabilities of convective parameters relevant for hail events in Germany and Europe, Atmospheric Research on ScienceDirect 123, 18, (2013); [Google Scholar]
  9. H. J. Punge, K. Bedka, M. Kunz, A. Werner, A new physically based stochastic event catalog for hail in Europe, Natural Hazards 73, 21, (2014); [CrossRef] [Google Scholar]
  10. K. A. Nicolaides, G. Photiou, K. Savvidou, A. Orphanou, S. C. Michaelides, T. S. Karakostas, D. Charalambous, C. Kannaouros, The impact of hail storms on the agricultural economy of Cyprus and their characteristics, Adv. Geosci., 17, 5, (2009); [Google Scholar]
  11. A. Pushparani Devi, Moirangthem Sanju Singh, Shubhashree Priyadarshinee Das, Jhilki Kabiraj, Effect of Climate Change on Vegetable ProductionA Review, Int. J. Curr .Microbiol. App. Sci. 6(10), 7, (2017); [CrossRef] [Google Scholar]
  12. E. E. Braun, S. Taylor Lovell, M. Babadoost, F. Forcella, S. Clay, D. Humburg, S. E. Wortman, Abrasive grit application in organic red pepper: An opportunity for integrating nitrogen and weed management, HortScience 54 (9), 8, (2019); [Google Scholar]
  13. D. Zugravescu, Gh. Manolea, L. Alboteanu, C. Şulea Iorgulescu, Anti-hail system geonomic component of modern science, Proceedings of the International Conference on RISK MANAGEMENT, ASSESSMENT and MITIGATION, 5, ISSN: 1790-2769, ISBN: 978-960-474-182-3 (2010); [Google Scholar]
  14. A. K. Arakelyan, Flaws and advantages of current and prospective anti-hail protection methods, stations and networks (Review), Global Advanced Research Journal of Agricultural Science (GARJAS) 7(12), 11 (2018); [Google Scholar]
  15. A. K. Arakelyan, A Way to Enhance Hail Prevention Technique and to Increase the Efficiency of Anti-Hail Protection of Unlimited Agricultural Areas, J Agron Agri Sci 2: 013 (2019); [Google Scholar]
  16. G. Manolea, I.L. Alboteanu, A. Novac, C. Sulea Iorgulescu, S. Stepan, Optimizing the Structure of the Rocket Launcher Monitoring System, 2019 International Conference on Electromechanical and Energy Systems (SIELMEN), Craiova, Romania, 5, (2019); [Google Scholar]
  17. Y. Shahak, Photoselective Netting: The Concept, Research and Implementation in Various Crops, ASHS Annual Conference, 8, (2011); [Google Scholar]
  18. S. K. Agrawal, Application of textile in agriculture, IJARSE 2 (7), 10, (2013); [Google Scholar]
  19. E. Cărpuş, A Dorogan, F. Burnichi, Agrotextile Systems Strategic Elements for Sustainable Development of the Agriculture, 7-th International Conference on Advanced Materials and Systems ICAMS, 5, (2018); [Google Scholar]
  20. K. Bhavani, N. Mallikarjun, N.M. Sunilkumar, Agro textiles Their applications in agriculture and scope for utilizing natural fibers in agro tech sector, International Journal of Applied Home Science, 4 (7&8), 10, (2017); [Google Scholar]
  21. S. G. Annapoorani, K. Saranya, Applications of Agricultural Textiles A Review, International Journal for Research in Engineering Application & Management (IJREAM), 4, ISSN: 2454-9150 Special Issue ICDOMP’19, 4, (2019); [Google Scholar]
  22. P. Marasovic, D. Kopitar, Overview and perspective of nonwoven agrotextile, TEXT LEATH REV 2 (1), 14, (2019); [CrossRef] [Google Scholar]
  23. M.A. Jones, Using light to improve commercial value, Horticulture Research 5, 47 (2018); [CrossRef] [PubMed] [Google Scholar]
  24. Y. Shahak, Y. Kong, K. Ratner, The wonders of yellow netting, Acta Hortic. 1134, 8, (2016); [Google Scholar]
  25. B. P. Baker, C. L. Mohler, Weed management by upstate New York organic farmers: strategies, techniques and research priorities, Renewable Agriculture and Food Systems, 30 (5), 10, (2014); [Google Scholar]
  26. E. Pannaci, B. Lattanzi, F. Tei, J., Non-chemical weed management strategies in minor crops: A review, Crop Protection 96, 15, (2017); [Google Scholar]
  27. B. Melander, N. Holst, I. A. Rasmussen, P. K. Hansen, Direct control of perennial weeds between crops e Implications for organic farming, Crop Protection 40, 7, (2012); [CrossRef] [Google Scholar]
  28. A. Peruzzi, M. Raffaelli, M. Ginanni, M. Fontanelli, C. Frasconi, An innovative selfpropelled machine for soil disinfection using steam and chemicals in an exothermic reaction, J. Biosystem Engineering 110, 9, (2011); [Google Scholar]
  29. A. Peruzzi, M. Raffaelli, C. Frasconi, M. Fontanelli, P. Bàrberi, Influence of an injection system on the effect of activated soil steaming on Brassica juncea and the natural weed seedbank J. Weed Research, 52, 13, (2012); [Google Scholar]
  30. M. Raffaelli, L. Martelloni, C. Frasconi, M. Fontanelli, S. Carlesi S., A. Peruzzi, A prototype band-steaming machine: Design and field application, J. Biosystem Engineering 144, 11, (2016); [Google Scholar]
  31. A. Koocheki, M. Nassiri, L Alimoradi, R. Ghorbani, Effect of cropping systems and crop rotations on weeds, Agron. Sustain. Dev. 29, 8 (2009); [Google Scholar]
  32. D. Weisberger, V. Nichols, M. Liebman M, Does diversifying crop rotations suppress weeds? A meta-analysis, PLoS ONE 14(7): e0219847, (2019); [CrossRef] [PubMed] [Google Scholar]
  33. S. Cordeau, R. G. Smith, E.R. Gallandt, B. Brown, P. Salon, A. DiTommaso, M.R. Ryan, Disentangling the Effects of Tillage Timing and Weather on Weed Community Assembly, J. Agriculture 7 (8), 66, 18, (2017); [CrossRef] [Google Scholar]
  34. S. Gruber,W. Claupein Effect of tillage intensity on weed infestation in organic farming, J. Soil & Tillage Research 105, 8, (2009); [Google Scholar]
  35. M. H. Jorgensen Chapter 3, The Effect of Tillage on the Weed Control: An Adaptive Approach, Biological Approaches for Controlling Weed, (2018) http://dx.doi.org/10.5772/intechopen.76704; [Google Scholar]
  36. L. Tang, C. Cheng, K. Wan, R. Li, D. Wang, Y. Tao, Impact of Fertilizing Pattern on the Biodiversity of a Weed Community and Wheat Growth, PLoS ONE 9(1): e84370., (2014); [CrossRef] [PubMed] [Google Scholar]
  37. A. A. Bajwa, Ehsanullah, S. A. Anjum, W. Nafees, M. Tanveer, H. S. Saeed, Impact of fertilizer use on weed management in conservation agriculture A Review, Pakistan J. Agric. Res. 27(1), 10 (2014); [Google Scholar]
  38. R.K. Dhall, Breeding for Biotic Stresses Resistance in Vegetable Crops: A Review, STM Journals 2015, RRJoCST 4 (1), 14, (2015); [Google Scholar]
  39. P. Dittmar, N. Boyd, R. Kanissery, Weed Management Principles in Commercial Vegetable Production, HS717/CV113, 6, (2018); [Google Scholar]
  40. A. Peruzzi, L. Martelloni, C. Frasconi., M. Fontanelli, M. Pirchio, M. Raffaelli, Machines for non-chemical intra-row weed control in narrow and wide-row crops: a review, Journal of Agricultural Engineering, XLVIII:583, 14, (2017); [Google Scholar]
  41. D.L. Shaner, H.J. Beckie H.J., The Future for Weed Control and Technology, Pest Management Science 70 (9), 11 (2014); [Google Scholar]
  42. J. Banks, G. Sandral, Report on weed control using hot water / steam and herbicides in the city of Joondalup, (2007) http://api.joondalup.wa.gov.au/files/councilmeetings/2007/attach11brf210807.pdf; [Google Scholar]
  43. A. M. Peerzada, B. S. Chauhan, Thermal Weed Control: History, Mechanisms, and Impacts in Jabran K., Chauhan B.S. (Eds) Non – Chemical Weed Control, Elsevier, Academic Press, 23, (2018); [Google Scholar]
  44. J. Ascard, Effect of flame weeding on weed species at different developmental stages, Weed Res. 35, 15, (1995); [Google Scholar]
  45. L. Martelloni, C. Frasconi, M. Fontanelli, M Raffaelli, A. Peruzzi, Mechanical weed control on small-size dry bean and its response to cross-flaming, SJAR 14 (1), 12, (2016); [Google Scholar]
  46. M. Raffaelli, M. Fontanelli, L. Martelloni, C. Frasconi, A. Peruzzi, Innovative strategy and machines for physical weed control in agriculture and urban areas, International Conference RAGUSA SHWA, Italy, 7, (2012); [Google Scholar]
  47. L. Martelloni, M. Fontanelli, C. Frasconi, M. Raffaelli, M. Pirchio, A. Peruzzi, A combined flamer-cultivator for weed control during the harvesting season of asparagus green spears, SJAR 15 (2), 10, (2017); [Google Scholar]
  48. B. Melander, B. Lattanzi, E. Pannacci, Intelligent versus non-intelligent mechanical intra-row weed control in transplanted onion and cabbage, J. Crop Protection 72, 8, (2015) [Google Scholar]
  49. M Siemens, Robotic Weed Control, Proceedings of the California Weed Science Society 66, 5, (2014); [Google Scholar]
  50. R. Lati, M. Siemens, J. Rachuy, S. Fennimore, Intra-Row Weed Removal in Broccoli and Transplanted Lettuce with an Intelligent Cultivator, Weed Technology 30 (3), 9, (2016); [Google Scholar]
  51. R. Smith, Evaluation of intelligent cultivators for use in lettuce production, UC Weed Science, ANR Blogs, (2016), https://ucanr.edu/blogs/blogcore/postdetail.cfm?postnum=19841&email=yes; [Google Scholar]
  52. Y. Zhang, E. S. Staab, D. C. Slaughter, D. K. Giles, D. Downey, Automated weed control in organic row crops using hyperspectral species identification and thermal micro-dosing, J. Crop Protection 41, 10 (2012); [CrossRef] [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.