https://chemical.journalspub.info/index.php?journal=JCSCR&page=issue&op=feedInternational Journal of Chemical Synthesis and Chemical Reactions2024-03-02T06:56:35+00:00Komalchemistry.editor@celnet.inOpen Journal Systems<p><strong><strong><span><strong><strong><span id="lblJournalName"> </span></strong></strong></span></strong><span id="lblJournalName"> International Journal of Chemical Synthesis and Chemical Reactions</span></strong></p><p><strong><strong><span> (IJCSCR)</span></strong></strong></p><p><strong> eISSN: <strong><span id="DataList1_ctl00_Label11">2582-5917</span></strong></strong></p><p><strong><strong><span> <a href="/index.php?journal=JCSCR&page=about&op=editorialTeam">Complete Editorial Board</a></span></strong></strong></p><p><strong> Scientific Journal Impact Factor (SJIF): <span>6.003</span></strong></p><p><strong><strong><span id="lblJournalName">International Journal of Chemical Synthesis and Chemical Reactions(IJCSCR): </span></strong></strong><span id="lblJournalName">It</span> <span id="lblDiscription">focuses on the material synthesis, mass balance, kinetic analysis and other related fields of chemical synthesis process and chemical reactions. Journal accepts both experimental and theoretical papers that fall under the scope of the journal. It's a biannual journal, started in 2015.</span></p><p><strong>Journal DOI no.: <strong>10.37628/IJCSCR</strong></strong></p><p><strong>Indexed in: Journal TOC, Google Scholar,<span>Advanced science index, <strong>Index Copernicus (<a href="https://journals.indexcopernicus.com/search/details?id=124802">ICV: 67.77)</a></strong></span></strong></p><p><strong>Readership:</strong><span> <strong>Graduates, Postgraduates, Research Scholars, Faculty</strong></span></p><p><strong>Focus and Scope Cover:</strong></p><p>• Chemical engineering<br />• Electrosynthesis<br />• Methods in Organic Synthesis<br />• Organic synthesis<br />• Peptide synthesis<br />• Reaction mechanism<br />• kinetic analysis<br />• Combustion<br />• Mass balance<br />• Emerging reactor technologies<br />• Materials Synthesis and Processing</p><p><span>All contributions to the journal are rigorously refereed and are selected on the basis of quality and originality of the work. The journal publishes the most significant new research papers or any other original contribution in the form of reviews and reports on new concepts in all areas pertaining to its scope and research being done in the world, thus ensuring its scientific priority and significance.</span></p><p><strong>Submission of Paper: </strong><strong></strong></p><p>All contributions to the journal are rigorously refereed and are selected on the basis of quality and originality of the work. The journal publishes the most significant new research papers or any other original contribution in the form of reviews and reports on new concepts in all areas pertaining to its scope and research being done in the world, thus ensuring its scientific priority and significance.</p><p>Manuscripts are invited from academicians, students, research scholars and faculties for publication consideration.</p><p>Papers are accepted for editorial consideration through email <strong>chemistry.journals@celnet.in </strong>or<strong> chemistry.editor@celnet.in</strong></p><p><strong>Subject: Chemical Engineering, Organic Synthesis, Electrosynthesis</strong></p><p><strong>Abbreviation: IJCSCR</strong></p><p><strong>Frequency</strong>: <strong>Two issues per year</strong></p><p><a href="http://journalspub.com/AllEditorsJournalwise.aspx?jid=69&jname=International%20Journal%20of%20Chemical%20Synthesis%20and%20Chemical%20Reactions"><strong>Editorial Board</strong></a></p><p><strong><a href="/index.php?journal=JCSCR&page=about&op=editorialPolicies#focusAndScope">Peer Reviewed Process</a></strong></p><p><a href="http://journalspub.com/pdf/Guidelines%20for%20authors.pdf"><strong>Instructions To Author</strong></a></p><p> </p><p><span><br /></span></p>https://chemical.journalspub.info/index.php?journal=JCSCR&page=article&op=view&path%5B%5D=1430Theoretical Insights Into Structure, Electronic Properties, and Ion-pair Interactions In Organopalladium Salts [Pd(p-XC6H3CHMeNH2) (tmeda)] [BF4] AND [Pd(p-XC6H3CHMeNH2) (tmeda)] [PF6] (X = H, F, Me)2024-03-02T06:56:35+00:00Sunil Kumar Patidarsunil87patidar@gmail.comRavi Vishwakarmasunil87patidar@gmail.comPankaj Kumar Bariyasunil87patidar@gmail.comMadhu Singh Singhsunil87patidar@gmail.comSonu Sensunil87patidar@gmail.comThe geometries of organopalladium salts [Pd(p-XC6H3CHMeNH2) (tmeda)] [BF4] and [Pd(pXC6H3CHMeNH2) (tmeda)] [PF6] (X = H, F, Me) (I-VI) have been optimized using BP86 and TPSS density functional at dispersion corrected DFT-D3(BJ) method. The optimized geometries of the salt [Pd(C6H4CHMeNH2) (tmeda)] [BF4] using TPSS functional in methanol slvent is in good agreement with available experimental data. The N1-Ha bond distances are longer than the N1-Hb bonds. The counterion strongly affects the noncovalent N1-Ha---F, N1-Hb---F, C1-H---F and C2-H---F bond distances. The N1-Ha----F bonding interactions are higher than the N1-Hb---F interactions. The cationic fragments are quite stronger to withdraw electron density from [PF6] - as compared to [BF4] - anion. The Mayer bond order values for N1-Ha bonds are significantly lower as compared to N1-Hb bonds. The Noncovalent interaction-reduced density (NCI-RDG) analysis showsthat the intermolecular interactions are attractive in nature. The ion pair dissociation energies in gas phase (79.7-86.8 kcal/mol) are higher than the solvent phase (6.7-7.5 kcal/mol). The cationic fragments [Pd(pXC6H3CHMeNH2) (tmeda)] + (X = H, F, Me), strongly interact with [PF6] - in salts IV-VI, then the [BF4] - in salts I-III.2024-03-01T05:41:06+00:00Copyright (c) 2024 International Journal of Chemical Synthesis and Chemical Reactionshttps://chemical.journalspub.info/index.php?journal=JCSCR&page=article&op=view&path%5B%5D=1429Green Chemistry Approach for the Preparation of Silver Nanoparticles: A Review2024-03-02T06:56:35+00:00P SUPRAJA GOUDpabbasupraja020@gmail.comSravani Vallelapabbasupraja020@gmail.comAreti Venkata Sree Vanpabbasupraja020@gmail.comAnitha Sadulapabbasupraja020@gmail.comThe word "nanoparticles" refers to particles within a size range of 10 and 100 nm. Nanotechnology is the topic that is growing the fastest because of its applications in science and technology to produce new at the nanoscale range. Silver is the metal of first preference among the various noble metals. The production of silver nanoparticles can be achieved by different methods such as: chemical method, biological method, green synthesis. The formation of silver nanoparticles by green synthetic methods is the primary focus of this review. The production of ecologically friendly silver nanoparticles requires two basic ingredients: a reducing bilogical agent and a silver metal ion solution. In addition to enzymes, certain plant parts such as leaves, fruits, flowers etc, have lately been used to make silver and gold nanoparticles. Silver nanoparticles can be extracted from many medicinal plants such as Saccharum officinarum, Helianthus annus, Cinnamomum camphora, Oryza sativa, Aloe vera, Capsicum annuum, Medicago sativa, Zea mays, and Magnolia Kobus in the biological and pharmaceutical field. Plant extracts-mediated synthesis is one of the various green synthesis techniques that has additional practical uses. The AgNPs can be prepared from different parts of the plants like: From Flowers, leaves, stems, roots and fruits. UV spectroscopy is used to characterise the silver nanoparticles, with wavelengths ranging from 340 to 740 nm. The dried silver nanoparticle powder underwent additional analysis using XRD and EDAX. SEM, or scanning electron microscopy, can be used to evaluate the size and shape of the silver nanoparticles.2024-02-27T12:21:27+00:00Copyright (c) 2024 International Journal of Chemical Synthesis and Chemical Reactionshttps://chemical.journalspub.info/index.php?journal=JCSCR&page=article&op=view&path%5B%5D=1360A study of mesomorphic properties of Rod shaped 1, 2, 4-triazine integrated imine compounds2023-06-14T08:56:14+00:00sushma .sushma10ms@gmail.comB. S. Priyasushma10ms@gmail.comS. Anandasushma10ms@gmail.comM. P. Sadashivasushma10ms@gmail.comK.M. Lokanatha Raisushma10ms@gmail.com<p>Synthesis of typical rod-like liquid crystals has a great interest in numerous applications. The model has a terminal chain attached to only one end of the central rigid core. At the other end of the rigid core is a functional group that can be either polar or nonpolar. There are three kinds of rod-like liquid crystal, in this segment applies specifically to materials with template designs. Generally, terminal groups which are polar and conjugated to the aromatic core be inclined to form nematic phases, whereas nonpolar not-conjugated groups lean toward forming smectic a and b. The studies mainly concentrated on nonpolar substituents to the terminal. Generally, terminal groups which are polar and conjugated to the aromatic core be inclined to form nematic phases, whereas nonpolar not-conjugated groups lean toward forming smectic a and b. The studies mainly concentrated on nonpolar substituents to the terminal. The present rod-shaped 1,2,4-triazine integrated imine compounds show various<br />mesophases like SmA, SmCa, and a few unidentified mesophases viz., SmX1, SmX2, etc. These chemicals exhibit a reversible photo-switching phenomenon that has important applications, according to preliminary tests.</p>2023-04-06T06:30:30+00:00Copyright (c) 2023 International Journal of Chemical Synthesis and Chemical Reactionshttps://chemical.journalspub.info/index.php?journal=JCSCR&page=article&op=view&path%5B%5D=1367Electrotrophs that Thrive in High Temperatures for the Microbial Electrosynthesis of Organic Materials (Microbial Electrosynthesis)2023-06-14T08:56:14+00:00Smrita Shastrismritashastri1998@gmail.com<p>Electrotrophs are a type of microorganism that can use electrons as an energy source for metabolic processes, such as the synthesis of organic compounds. This makes them ideal for use in microbial electrosynthesis (MES), a technology that harnesses these organisms to produce valuable chemicals and fuels from carbon dioxide and other renewable sources. Microbial electrosynthesis is a viable technique for converting carbon dioxide to various organic products and transportation fuels, but it needs to be optimized before it can be commercialized. Product generation rates may be accelerated by cathodes that facilitate electron transport between the electrode and the microorganism. High temperature electrotrophs are a class of these microorganisms that can grow and function at elevated<br />temperatures, making them particularly suitable for use in MES processes that require high temperatures. One of the main advantages of using high-temperature electrotrophs for MES is that they can operate at temperatures that are significantly higher than those used in traditional biological<br />processes, which typically range from 20-40°C. This makes them particularly suitable that require high-temperature conditions, such as the production of biofuels from lignocellulosic feedstocks, the conversion of waste materials into value-added products, and the production of fine<br />chemicals. To test this hypothesis, biofilms of Sporomusa ovata, that are effective at acetic electrosynthesis, where cultivated on a variety of electrocatalysts and the rate of acetic synthesis was recorded over time.</p>2023-02-19T00:00:00+00:00Copyright (c) 2023 International Journal of Chemical Synthesis and Chemical Reactionshttps://chemical.journalspub.info/index.php?journal=JCSCR&page=article&op=view&path%5B%5D=1335Synthesis of Low Cost Artificial Sand From Fly ash and its Application as a Filter Material2023-06-14T08:56:14+00:00G. Venkateshwar Reddyvenkisri936@gmail.comPupalwad Arti Sudamvenkisri936@gmail.com<p>The usage of natural river sand is increasing vastly. Geopolymers are materials with three-dimensional alumina silicate structures that have a high mechanical strength and can be used as an alternative to Portland cement. The probability of using Natural river sand can also be replaced with geopolymer synthetic sand. There are many properties which may lead the scarcity of natural riversand they are Because of landslides, tsunamis and erosion. The GPSS can be used as mixture in cement and mortar. The properties or values of GPSS shows similar to natural river sand for grain size distribution, friction angle, permeability andspecific gravity. GPSS has a pH of 11.72 and a TDS of 768 mg/L, whereas<br />natural river sand has a pH of 7.40 and a TDS of 452 mg/L.In comparison to NRS sand, GPSS has a higher pH value and lower TDS. Embankment dam failures is becoming a worldwide occurrence, with a devastating impact on civilian lives. Moreover, Natural, and man-made dam failures formed, are susceptible to damage unless there is adequate stability. The bulk of the seepage failures are linked to intense water seepage. The seepage failures can be examined by using terzagi theory. Examination of dam stability due to massive rains is a critical issue to examine in the area with high seepage failures. This study is aimed towards exploring the effect of geotextile and artificial sand as seepage barrier<br />through embankment dams. This paper aims to research on the impact of seepage failures through embankment dams by using Geo Studio 2012 application using NRS and GPSS. The major goal of this research is to raise awareness about the consequences of high seepage rates (discharge) through<br />embankment dams.</p>2023-02-08T00:00:00+00:00Copyright (c) 2023 International Journal of Chemical Synthesis and Chemical Reactionshttps://chemical.journalspub.info/index.php?journal=JCSCR&page=article&op=view&path%5B%5D=1333Extraction of Xylanases from Media Based on three Agricolous Co-products by An Aqueous Two-phase System2023-06-14T08:56:14+00:00Ourdia Nouara Kernounouara89@gmail.comKamelia Kerdouchenouara89@gmail.comPr. Nawel Boucherbanouara89@gmail.comPr. Khodir Madaninouara89@gmail.com<p><em>Jonesia denitrificans BN13 grows very well on a medium made out of agricultural byproducts like orange peel, esparto grass, and retam; the relative enzyme activity of these three substrates was 0.662, 0.711, and 0.835 U/ml, respectively First time xylanases were effectively extracted utilising aqueous two-phase system (ATPS) that had 3.5% PEG, 14% KH<sub>2</sub>PO<sub>4</sub>/K<sub>2</sub>HPO<sub>4</sub>, and 9% KI, The inclusion of cells resulted in much improved output from the system, which is based on the technology's ability to work on the basis of the assumption that proteins may be selectively partitioned between the two aqueous phases. In the culture medium that is based on orange peel, a yield of 72% of the enzyme activity is found in the upper phase with a partition coefficient of 2.75 and a purification factor of 1.38. In the medium that is based on alfa, 57.5% of the enzyme activity is located in the lower phase with a partition coefficient of 0.67 and a purification factor of 1.78. In the medium that is based on retam, a yield of 82% of the enzyme activity.</em></p>2023-02-04T04:47:47+00:00Copyright (c) 2023 International Journal of Chemical Synthesis and Chemical Reactions