Study on the Effect of Rainfall Level on the Size of Silver Nanoparticles Synthesized by Plants of the Lamiaceae Family in Different Regions of Iran

SABERIYAN SANI, MARYAM NEGAR; Sayadi Anari, Mohammad Hussein

|
|
|
How to cite
RIS EndNote BibTeX APA MLA Harvard Vancouver
|
Share

	Study on the Effect of Rainfall Level on the Size of Silver Nanoparticles Synthesized by Plants of the Lamiaceae Family in Different Regions of Iran
Article 3, Volume 5, Issue 3, Summer 2018, Page 513-522 PDF (337.58 K)
Document Type: Review
Authors
MARYAM NEGAR SABERIYAN SANI ¹; Mohammad Hussein Sayadi Anari²
¹PhD student Department of Environmental Engineering, College of Natural Resources and Environment, University of Birjand
²Department of Environmental Engineering, College of Natural Resources and Environment, University of Birjand
Abstract
Nanotechnology could be a very important field of recent research dealing with medical, industrial, environment. Silver nanoparticles are the topics of researchers because of their distinctive properties (size, shape depending optical, antimicrobial, and electrical properties). The synthesis of safe nanoparticles by biological organisms is recommended due to the environmental friendliness and low costs compared to physical and chemical methods. Recently, researchers tend to use a biological synthesis of nanoparticles by biological methods such as plants. This research aimed to study on the rainfall level on the biosynthesis of silver nanoparticles by Lamiaceae family plants in different regions of Iran. T-test student was used to examining the relationship between the size of nanoparticles and rainfall, using spss version 22 software. The study shows phenol concentration in low rainfall areas is more than high rainfall area, which is the main factor for the synthesis of nanoparticles. The result of the study demonstrated that the highest size of synthesized nanoparticle is 50 nm and the lowest size 10 nm, which are related to high rainfall and low rainfall regions respectively. The results showed the relationship between synthetic nanoparticles sizes and rainfall are significant p-value<0.05. As the present study could be, conclude that the rainfall amount is effectively factor for the synthesis of the nanoparticle while other factors such as temperature, altitude and climate play a key role for properties of the plant, which is affect for size of nanoparticles.
Keywords
Plant; Green synthesis; Nanoparticle; Climate


References
[1] M. G. Acimovic, J. Korac, G. Jacimovic, S. Oljaca, L. Djukanovic, V. Vuga, Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 42, 232 (2014). [2] Sh. Ahmeda, A. S. Ali, C. SaiqaIkram, Journal of Photochemistry and Photobiology B: Biology, 166, 272 (2017). [3] A. Akbari, K. Larijani, Nat. Con. New Technologies in Nanocomposites, 5,1 ( 2016). [4] A. R. Allafchian, Z. Majidian, V. Ielbeigi, M. Tabrizchi, J. Nanostructure in Chemistry, 6, 129 (2016). [5] M. Baghayeri, B. Mahdavi, Z. Hosseinpor, M. Abadi, S. Farhadi, J. Organomet, Chem, 4, 129 (2017). [6] F. D. Nayeri, M. Mirhoseini, S. Mafakheri, J. Plant. Res., 8, 93 (2016). [7] M. Ghaedi, M. Yousefinejad, M. Safarpoor, H. Khafri, M. K. Purkait, J. Ind. Eng. Chem. Res, 31, 167 (2015). [8] F. Ghorbani, M. Bahraini, Nat. Con. New Findings in the Environment and Agricultural Ecosystems, 6, 129 ( 2014). [9] Z. Haghighi, H. Abbaspour, N. Karimi, A. Fattahi, J. Appl. Sci., 6, 69 (2016). [10] S. Hasan, Int. J. Recent. Sci. Res. 2277, 2502 (2015). [11] R. Heidari, M. Rasgidipoor, M. Azadpoor, J. NLM., 26, 99 ( 2016). [12] S. Jafarirad, M. Kordi, M. Kosari-Nasab, J. Inorganic. Nano. Met. Chem.,47, 632 (2017). [13] Z. Aghajani Kalaki, R. Safaeijavan, M. Mahdavi Ortakand, BJPS. 8, 24 (2017). [14] S. Kumar, A. Yadav, M. Yadav, J. P. Yadav, J. f. BMC research notes, 10, 60 (2017). [15] A. Kumar, M. Yusuf, Ch. ChandBanerjeea, Biotechnol. Adv, 31, 346 (2013). [16] T. Mohsali, S. Porseyedi, J. Biotechnol, 6, 11 ( 2015). [17] M. Nasrollahzadeh, S. Sajadi, A. Rostami-Vartooni, S. Alizadeh, ‎J. Colloid. Interface. Sci., 466, 360 (2016). [18] M. Nasrollahzadeh, S. Sajadi, A. Rostami-Vartooni and S Alizadeh, ‎J. Colloid. Interface. Sci., 466,113 (2016). [19] S. Nikrui, S. A. Mehdiyan, Nat. Con. Biotechnology New Findings, (2015). [20] S. Pirtarighat, M. Ghannadnia, S. Baghshahi, Nanomed. J., 4, 184 (2017). [21] M. Rahmatian, M. Dadmehr, A. Tavasoli, Nat. Con. Biotechnology New Findings, 4, 180 ( 2017). [22] H. Rai-Dehagi, J. Razmjoo, M. R. Sabzaliyan, A. Arzani, J. Plant. Process. Funct, 4, 58 (2014). [23] Z. Safi, K. Saeid, Z. Lorigooini, H. A. Shirmardi, J. Shahrekord Uuniversity of Medical Sciences, 2, 134 (2016). [24] N. Seyedi, H. Sheibani, K. Saidi, J. Catalysis Today, 4, 184 ( 2017). [25] K. Princess, M. Gholami, H. Esmail, Nat. Con, Applied Microbiology in Iran, 5, 184 ( 2017). [26] H. Ya'qub, S. Kavoosi, JCMM, 4, 184 ( 2017). [27] R. Ahmadi, M. Ebrahimikia, Phys. Chem. Res., 5, 617 (2017). [28] R. Ahmadi, T. Boroushaki, M. Ezzati, Int. J. Nano. Dimens., 6, 19 (2015). [29] R. Ahmadi, M. R. Jalali Sarvestani, B. Sadeghi, Int. J. Nano. Dimens., 9, 325-335.
Statistics Article View: 167 PDF Download: 146