Sami Publishing Company (SPC) Asian Journal of Nanosciences and Materials 2645-775X 2588-669X 1 1 2018 03 01 The study of range-scaling transformation of nanoparticle compounds on thin films of gold-centered monolayer protected nanoparticles by molecular modeling 1 10 EN Mehrdad Shahpar Director of Ilam Petrochemical Company. shahpar2012@gmail.com Sharmin Esmaeilpoor Department of Chemistry, Payame Noor University, P.O. BOX 19395-4697, Tehran, Irann sharminesmaeilpoor@yahoo.com 10.26655/ajnanomat.2018.1.1 A quantitative structure–retention relation (QSRR) study was conducted on the range-scaling transformation (Xa) of the nanoparticle compounds which obtained by comprehensive two-dimensional gas chromatography (GC×GC) stationary phases consisting of thin films of the gold-centered monolayer protected nanoparticles (MPNs) system. The genetic algorithm was used as descriptor selection and model development method. Modeling of the relationship between the selected molecular descriptors and the retention time was achieved by linear (partial least square; PLS) and nonlinear (Levenberg-Marquardt artificial neural network; L-M ANN) methods. Linear and nonlinear methods resulted in an accurate prediction whereas more accurate results were obtained by L-M ANN model. Nanoparticle compounds,Gold-centered monolayer protected nanoparticles,Comprehensive two-dimensional gas chromatography,QSRR,Levenberg-Marquardt artificial neural network https://www.ajnanomat.com/article_57276.html https://www.ajnanomat.com/article_57276_220b3f93bb21b517ceb26ef51bb76ec5.pdf

Sami Publishing Company (SPC) Asian Journal of Nanosciences and Materials 2645-775X 2588-669X 1 1 2018 03 01 Silica supported-boron sulfonic acid: a versatile and reusable catalyst for synthesis of bis(indolyl)methane in solvent free and room temperature conditions 11 18 EN Sami Sajjadifar 0000-0001-8661-1264 Department of Chemistry, Payame Noor University, PO BOX 19395-4697 Tehran, Iran info@ajnanomat.com Ghobad Mansouri 0000-0002-0589-2832 Department of Chemistry, Payame Noor University, PO BOX 19395-4697 Tehran, Iran mansouri.gh@gmail.com Shefa Miraninezhad Department of Chemistry, Payame Noor University, PO BOX 19395-4697 Tehran, Iran shefamiriani@yahoo.com 10.26655/ajnanomat.2018.1.2 Silica supported-boron sulfonic acid (SBSA) was used as a cheap and mild bronsted acidic in the reaction of indole with aldehydes to afford the corresponding bis(indolyl)methanesin in solvent free grinding and room temperature. The catalyst is also effective in the reaction in good yields. This methodology offers several advantages, such as good yields, reusability of catalyst, short reaction times, simple procedure, and mild conditions. The catalyst can be recovered and reused without loss of activity. The work-up of the reaction consists of a simple filtration, followed by concentration of the crude product and purification. Indole,Bis(indolyl)methane,Boron Sulfonic Acid,Aldehyde,Synthesis https://www.ajnanomat.com/article_58120.html https://www.ajnanomat.com/article_58120_228a5e6048cf58a741580a4d52712930.pdf

Sami Publishing Company (SPC) Asian Journal of Nanosciences and Materials 2645-775X 2588-669X 1 1 2018 03 01 Green synthesis of nanosilver particles from extract of Dracocephalum Lindbergii 19 24 EN M. Halimi 0000-0003-4074-8681 Department of Chemistry, Payame Noor University, P.O. Box 19395-4697 Tehran, Iran majid_halimi@pnu.ac.ir M. Nasrabadi Department of Chemistry, Payame Noor University, P.O. Box 19395-4697 Tehran, Iran malnasr2002@yahoo.com N. Soleamani Department of Chemistry, Payame Noor University, P.O. Box 19395-4697 Tehran, Iran n.solimane@yahoo.com N. Rouhani Department of Chemistry, Payame Noor University, P.O. Box 19395-4697 Tehran, Iran rouhani.neda@yahoo.com 10.26655/ajnanomat.2018.1.3 We describe the synthesis of silver nanoparticles (Ag-NPs) using aqueous extract of Dracocephalum lindbergii . UV–visible spectroscopy, X-ray diffraction (XRD), scanning electron microscopy (SEM), and X-ray energy dispersive spectrophotometer (EDX) were performed to ascertain the formation of Ag-NPs. UV-visible absorption spectra of the reaction medium containing silver nanoparticles showed maximum absorbance at 416 nm. The XRD pattern revealed the crystalline structure of SNPs. The SEM analysis showed the size and shape of the nanoparticles. The environmental friendly method provides simple, easy and cost effective faster synthesis of nanoparticles than chemical methods and can be used in several areas such as food, medicine. Green nanoscience,Biological synthesis,Dracocephalum lindbergii,Nanotechnology,Silver nanoparticle https://www.ajnanomat.com/article_57714.html https://www.ajnanomat.com/article_57714_bd7d08de42f6f913b6d74498e2624a43.pdf

Sami Publishing Company (SPC) Asian Journal of Nanosciences and Materials 2645-775X 2588-669X 1 1 2018 03 01 Theoretical analysis of the retention behavior of pesticides and active pharmaceutical compounds in wastewater and river waters in liquid chromatography–quadrupole-time-of-flight mass spectrometry 25 35 EN Mehrdad Shahpar Director of Ilam Petrochemical Company shahpar2012@gmail.com Sharmin Esmaeilpoor Department of Chemistry, Payame Noor University, P.O. BOX 19395-4697, Tehran, Iran sharminesmaeilpoor@yahoo.com 10.26655/ajnanomat.2018.1.4 The pesticides and active pharmaceutical compounds in water can potentially causedamage, including theincreased cancer risk; liver, and kidney. A quantitative structure–retention relationship (QSRR) was developed using the partial least square (PLS), Kernel PLS (KPLS), and Levenberg-Marquardt artificial neural network (L-M ANN) approach for chemometrics study. The data contained retention time (RT) of the 87 pesticides and active pharmaceutical compounds in wastewater and river waters. Genetic algorithm was employed as a factor selection procedure for PLS and KPLS modeling methods. The results showed that, the GA-PLS descriptors are selected for L-M ANN. Finally a model with a low prediction error and a good correlation coefficient was obtained by L-M ANN. Water Pollution,Organic contaminants,Pesticides,Pharmaceuticals,LC–QTOFMS https://www.ajnanomat.com/article_57713.html https://www.ajnanomat.com/article_57713_7a3bf566a75a38ab18060e741fb9d493.pdf

Sami Publishing Company (SPC) Asian Journal of Nanosciences and Materials 2645-775X 2588-669X 1 1 2018 03 01 Facile green synthesis of fluorescent carbon quantum dots from citrus lemon juice for live cell imaging 36 46 EN Aschalew Tadesse 0000-0001-6962-1479 Department of Inorganic and Analytical chemistry, Andhra University, Visakhapatnam-530003, India | Department of Applied Chemistry, AdamaScience and Technology University, 1888, Ethiopia asche.best@gmail.com Dharmasoth Rama Devi AU College of Pharmaceutical Science, Andhra University, Visakhapatnam-530003, India ramajoy90@gmail.com Mebrahtu Hagos 0000-0001-5555-173X Department of Inorganic and Analytical chemistry, Andhra University, Visakhapatnam-530003, India | Faculty of Natural and Computational Sciences, Woldia University, 400, Ethiopia hagosmebrahtu@gmail.com Gangarao Battu AU College of Pharmaceutical Science, Andhra University, Visakhapatnam-530003, India ganga.battu@gmail.com Keloth Basavaiah Department of Inorganic and Analytical chemistry, Andhra University, Visakhapatnam-530003, India klbasu@gmail.com 10.26655/ajnanomat.2018.1.5 Facile and green one pot hydrothermal method was used for synthesis of fluorescent carbon quantum dots (CQDs) using citrus lemon juice as precursor. The synthesized CQDs were characterized using UV–Vis spectrophotometer, fluorescence spectrometer, transmission electron microscopy (TEM), X-ray diffraction (XRD), Fourier transform infrared spectrometer (FTIR), field emission scanning electron microscope equiped with energy dispersive X-ray spectroscopy (FESEM-EDS) and fluorescence microscopy. The obtained CQDs have high photoluminescence of 10.20% quantum yield. The photoluminescence intensity of CQDs depends on pH of the solution and maximum intensity obtained at pH of 6. The particle size of the carbon dots were distributed in narrow range of 2–10 nm with an average of 5.8 nm. The highly water soluble CQDs have high cell viability even at high concentration which rich up to 85%. MTT assay was used to investigate the potential application of CQDs and the results indicated that the material can be used as florescent probe in the cell imaging. carbon quantum dots,citrus lemon juice,fluorescent,Hydrothermal method,cell imaging https://www.ajnanomat.com/article_57712.html https://www.ajnanomat.com/article_57712_c180ebf10d888464520073be893327fb.pdf

Sami Publishing Company (SPC) Asian Journal of Nanosciences and Materials 2645-775X 2588-669X 1 1 2018 03 01 Mathematical Properties and Computations of Banahatti indices for a Nano-Structure "Toroidal Polyhex Network" 47 51 EN Shama Firdous Department of Mathematics and Statistics, The University of Lahore, Lahore, Pakistan shamafirdous4@gmail.com Waqas Nazeer Divisionof Science and Technology, University of Education, Lahore, 54000, Pakistan nazeer.waqas@ue.edu.pk Mohammad Reza Farahani Department of Applied Mathematics of Iran University of Science and Technology (IUST), Narmak, Tehran 16844, Iran mrfarahani88@gmail.com 10.26655/ajnanomat.2018.1.6 Abstract: Let G be the connected graph with vertex set V(G) and edge set E(G).The first and second K Banhatti indices of G are defined as <em>B₁^(G)=Σ_ue[d_G (u) +d_G (e)] and B₂^(G)=Σ_ue[d_G (u) +d_G (e)]</em> where ^<em>ue</em>means that the vertex ^u and edge <em>^e</em> are incident in G.The first and second K hyper Banhatti indices of G are defined as <em>HB₁(G) = Σ_ue[d_g(u) + d_G(e)]²</em> and <em>HB₂(G) = Σ_ue[d_g(u) d_G(e)]²</em> respectively . In this paper, we compute the first and second K Banhatti indices of toroidal polyhex network. In addition, the first and second K hyper Banhatti indices of toroidal polyhex networks are determined. <br /><br />Keywords: Topological index, Banhatti index, Network. topological index,Banhatti index,network https://www.ajnanomat.com/article_58128.html https://www.ajnanomat.com/article_58128_46c1108124798e40eb03f99aa3836c03.pdf