Citations (35)
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Angel De Souza-Torres, Lilita Sueiro-Pelegrín, Miguel Zambrano-Reyes, Idalberto Macías-Socarras, Mario González-Posada & Dagoberto García-Fernández. (2020) Extremely low frequency non-uniform magnetic fields induce changes in water relations, photosynthesis and tomato plant growth. International Journal of Radiation Biology 96:7, pages 951-957.
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Malka N. Halgamuge. (2017) Review: Weak radiofrequency radiation exposure from mobile phone radiation on plants. Electromagnetic Biology and Medicine 36:2, pages 213-235.
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R. Radhakrishnan & B.D.
Ranjitha Kumari. (2013) Protective role of pulsed magnetic field against salt stress effects in soybean organ culture. Plant Biosystems - An International Journal Dealing with all Aspects of Plant Biology 147:1, pages 135-140.
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Angel De Souza, Lilita Sueiro, Luis Manuel González, Luis Licea, Elia Porras Porras & Fidel Gilart. (2008) Improvement of the Growth and Yield of Lettuce Plants by Non-Uniform Magnetic Fields. Electromagnetic Biology and Medicine 27:2, pages 173-184.
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Rajkumar Prajapati, Sunita Kataria, Rekha Gadre, Marco Landi & Meeta Jain. (2023) Unveiling the Mechanisms Underpinning Alleviation of Mercury Toxicity by Static Magnetic Field Treatment in Soybean. Journal of Plant Growth Regulation.
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Sien Chen, Dongli Yang, Qingxin Wang, Xueying Huang, Hongqiang Ren & Ke Xu. (2022) Study on the advanced nitrogen removal under low temperature by biofilm on weak magnetic carriers. Bioresource Technology 360, pages 127580.
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M.T. Upadyshev, I.M. Kulikov, V.I. Donetskich, A.D. Petrova, K.V. Metlitskaya & G.Yu. Upadysheva. (2021) Magnetic-pulse processing at micropropagation and cleaning up of fruit and small fruit crops from viruses. Acta Horticulturae:1324, pages 105-110.
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Canan Ulgen, Arzu Birinci Yildirim, Günce Sahin & Arzu Ucar Turker. (2021) Do magnetic field applications affect in vitro regeneration, growth, phenolic profiles, antioxidant potential and defense enzyme activities (SOD, CAT and PAL) in lemon balm (Melissa officinalis L.)?. Industrial Crops and Products 169, pages 113624.
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Marjan Diyanat, Pouya Sonboli-Hamedani & Fereidoon Ghasem-khan ghajar. (2021) Interaction of Magnetic Field and Dormancy Breaking Treatments on Germination and Seedling Growth of Some weed Species. Iranian Journal of Seed Research 8:1, pages 105-122.
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Anis Fatima, Sunita Kataria, Rajkumar Prajapati, Meeta Jain, Ashish K. Agrawal, Balwant Singh, Yogesh Kashyap, Durgesh Kumar Tripathi, Vijay Pratap Singh & Rekha Gadre. (2020) Magnetopriming effects on arsenic stress‐induced morphological and physiological variations in soybean involving synchrotron imaging. Physiologia Plantarum.
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Canan ULGEN, Arzu YILDIRIM & Arzu TURKER. (2020) Enhancement of Plant Regeneration in Lemon Balm (Melissa officinalis L.) with Different Magnetic Field ApplicationsEnhancement of Plant Regeneration in Lemon Balm (Melissa officinalis L.) with Different Magnetic Field Applications. International Journal of Secondary Metabolite 7:2, pages 99-108.
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Xiumei Liu, Lu Wang, Ye Wei, Zhihao Zhang, Hong Zhu, Linggang Kong, Shiyuan Meng, Chengdong Song, Huatian Wang & Fengyun Ma. (2020) Irrigation with magnetically treated saline water influences the growth and photosynthetic capability of Vitis vinifera L. seedlings. Scientia Horticulturae 262, pages 109056.
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L. Baghel, S. Kataria & K. N. Guruprasad. (2018) Effect of static magnetic field pretreatment on growth, photosynthetic performance and yield of soybean under water stress. Photosynthetica 56:2, pages 718-730.
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Sunita Kataria, Lokesh Baghel & K.N. Guruprasad. (2017) Pre-treatment of seeds with static magnetic field improves germination and early growth characteristics under salt stress in maize and soybean. Biocatalysis and Agricultural Biotechnology 10, pages 83-90.
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AMEETA SHARMA & SHEFALI SHEKHAWAT. (2017) An overview of magnetic field exposure on germination behavior of seeds under saline stress. International Journal of pharma and Bio Science 8:1.
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Soheil Karimi, Saeid ESHGHI, Saeid KARIMI & Saman HASAN-NEZHADIAN. (2017) Inducing salt tolerance in sweet corn by magnetic priming. Acta agriculturae Slovenica 109:1, pages 89-102.
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Lokesh Baghel, Sunita Kataria & Kadur Narayan Guruprasad. (2016) Static magnetic field treatment of seeds improves carbon and nitrogen metabolism under salinity stress in soybean. Bioelectromagnetics 37:7, pages 455-470.
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Gajendra R. Rathod & Anjali Anand. (2015) Effect of seed magneto-priming on growth, yield and Na/K ratio in wheat (Triticum aestivum L.) under salt stress. Indian Journal of Plant Physiology 21:1, pages 15-22.
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Jaime A. Teixeira da Silva & Judit Dobránszki. (2015) Magnetic fields: how is plant growth and development impacted?. Protoplasma 253:2, pages 231-248.
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Senavirathna Mudalige Don Hiranya JayasankaTakashi Asaeda. (2014) The significance of microwaves in the environment and its effect on plants. Environmental Reviews 22:3, pages 220-228.
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Angel De Souza, Dagoberto García, Lilita Sueiro & Fidel Gilart. (2014) Improvement of the seed germination, growth and yield of onion plants by extremely low frequency non-uniform magnetic fields. Scientia Horticulturae 176, pages 63-69.
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Yurii I. Novitskii, Galina V. Novitskaya & Yurii A. Serdyukov. (2014) Lipid utilization in radish seedlings as affected by weak horizontal extremely low frequency magnetic field. Bioelectromagnetics 35:2, pages 91-99.
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Fatemeh Abdollahi, Vahid Niknam, Faezeh Ghanati, Faribors Masroor & Seyyed Nasr Noorbakhsh. (2012)
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Basant L. Maheshwari & Harsharn Singh Grewal. (2009) Magnetic treatment of irrigation water: Its effects on vegetable crop yield and water productivity. Agricultural Water Management 96:8, pages 1229-1236.
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Grazia Trebbi, Francesco Borghini, Lisa Lazzarato, Patrizia Torrigiani, G. Lorenzo Calzoni & Lucietta Betti. (2006) Extremely low frequency weak magnetic fields enhance resistance of NN tobacco plants to tobacco mosaic virus and elicit stress‐related biochemical activities. Bioelectromagnetics 28:3, pages 214-223.
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D. D. Sandu, C. Goiceanu, A. Ispas, I. Creanga, S. Miclaus & Dorina E. Creanga. (2005) A preliminary study on ultra high frequency electromagnetic fields effect on black locust chlorophylls. Acta Biologica Hungarica 56:1-2, pages 109-117.
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