Theme: “Focusing on Advanced Methodologies and Techniques in Synthetic Organic Chemistry”
We take immense pleasure and honour to welcome professional chemists, experience researchers, professors, scientific communities, delegates, students, business professionals and executives from all over the globe to attend the Organic Chemistry 2022 conference. The Conference is scheduled to be a two-day interactive event where participants will be indulged to learn, discuss and share their knowledge through various activities such as poster presentations, speeches, talk sessions, and workshops.
Organic Chemistry 2022 welcomes you to attend “5th International Conference on Organic Chemistry” on April 25-26, 2022 at Toronto, Canada, Webinar with an innovative theme “Focusing on advanced Methodologies and techniques in Organic Chemistry”. This International conference (Organic Chemistry 2022) anticipates hundreds of delegates including keynote speakers, Oral presentations by renowned speakers and poster presentations by students besides delegates around the world. This conference perhaps a giant event that creates an ideal platform to share expertise addressing current methodologies and techniques involved in Organic Chemistry. It will be a wonderful opportunity for all the attendees as it provides an international networking opportunity to collaborate global class Organic associations
Organic chemistry is a field of science which includes study the structure, properties, composition, reactions to create new molecules and explore the properties of existing compounds. The conference covers the wide range of expertise in the field of chemistry encouraging researchers for presentation, communication and discussion of research results carried out in academia and industry.
Organic Chemistry 2022 is comprised of 20 tracks designed to offer comprehensive sessions that address current issues in Organic Chemistry Congress 2022.
- Organic Chemists
- Professors in Chemistry
- Associated and Assistant Professors in Organic Chemistry
- Post-doctoral and Researchers in Chemistry
- Heads of Chemical Departments
- Post Graduates and Graduates in Medicinal Chemistry
- Laboratory Chemists
- Chemical Scientists
- Directors, Presidents and CEO’s from industries and companies.
- Delegates from various Pharma and instrumental companies.
Track 1: Organic Chemistry
Organic chemistry is the study of the structure, properties, composition, reactions, and preparation, of organic compounds, which contain carbon in covalent bonding. Carbon has four valence electrons and so can create four bonds in accordance with octet rule. Organic compounds usually are large and can have several atoms and molecules bonded together. Organic molecules can be large, and they comprise the structural components of living organisms: carbohydrates, proteins, nucleic acids, and lipids. Carbon with its valence of four forms single, double, triple bonds, plus structures with delocalized electrons.
Types and characterization of organic compounds
- Functional groups
- Aliphatic and aromatic compounds
- Heterocyclic compounds
- Efficiency in organic synthesis
- Organic synthesis for materials science
- Organic synthesis for life science
Track 2: Bioorganic Chemistry
Nucleic acids are biopolymers or large biomolecules essential for all renowned forms of life. Nucleic acids that embrace DNA (deoxyribonucleic acid) and RNA (ribonucleic acid) are made up of monomers called nucleotides. If the sugar is ribose the compound is RNA. Once all 3 elements are combined they type a macromolecule. Nucleotides are called phosphate nucleotides. In organic chemistry, amino acids having each the paraffin and the acid teams attached to the first (alpha-) atom have particular importance known as 2-, alpha-, or α-amino acids (generic formula H2NCHRCOOH in most cases wherever R is an organic substituent referred to as a "side-chain" often the term "amino acid" is used to refer specifically to those.
- Classification of amino acids
- Peptides sequence analysis
- Stereochemistry of amino acids
- Acid-base behaviour of amino acids
- Synthesis of amino acids
- Reactions of amino acids
- Peptide structure amino acid analysis
- Classification of carbohydrates
- Fischer projections and the DL notational system
- Disaccharides and polysaccharides
- Epimerization and isomerisation
Track 3: Stereochemistry
The study of stereochemistry focuses on stereoisomers. The isomers have the same molecular formula and same number of bonded atoms, but differ in the three-dimensional orientations of their atoms in space. Stereo chemistry includes organic, inorganic, biological, physical and especially supra- molecular chemistry. The effect on the physical or biological properties these relationships impart upon the molecules in question, and the manner in which these relationships influence the reactivity of the molecule.
- Properties of Stereoisomers
- Separation of Stereoisomers
- Heterotopic ligands and faces
- Chiroptical properties
Track 4: Catalysis of Organic Compounds
Catalysed reactions have a lower energy rate limiting than the corresponding un-catalysed reaction leading to a better reaction rate at a similar temperature and for similar chemical concentrations. However, the detailed mechanics of chemical change is complicated. Catalysts could affect the reaction atmosphere favourably or bind to the reagents to polarize bonds, for e.g. acid catalysts for reactions of carbonyl compounds or type specific intermediates that don't seem to be created naturally like osmate esters in osmium tetroxide-catalysed hydroxylation of alkenes or cause dissociation of reagents to reactive forms like chemisorbed hydrogen in chemical reaction.
- Heterogeneous catalysts
- Homogenous catalysts
- Catalyst characterization methods
- Catalyst formulation and preparation methods
- Mechanism of catalytic reactions
Organic synthesis is a special branch of chemical synthesis and is concerned with the intentional construction of organic compounds. Organic molecules are more complex than inorganic compounds, and their synthesis has developed into one of the most important branches of organic chemistry. Organic molecules are described has additional drawings or structural formulas, combinations of drawings and chemical symbols. Lewis structures simplest model in addition brought up as Lewis-dot diagrams show the bonding relationship between atoms of a molecule and thus the lone pairs of electrons among the molecule. Lewis structures can also be useful in predicting molecular pure mathematics in conjunction with hybrid orbitals. Resonance structures are used once one Lewis structure to determine the ionic bonding one molecule cannot fully describe the bonding that takes place between shut atoms. Organic reactions are chemical reactions involving organic compounds.
- Methodology and applications
- Stereo selective synthesis
- Synthesis design
- Chem informatic tools for drug discovery
- Resonance and ionic bonds
- Polar covalent bonds and multiple bonding
Theories of chemical structure was first developed by August Kekule, Archibald Scott Couper, and Aleksandr Butlerov, among others, from about 1858. These theories were first to determine the chemical compounds are not a casual cluster of atoms and functional groups, but relatively had a definite order defined by the valency of the atoms composing the molecule, giving the molecules a 3-D structure that could be determined or solved.
In the field of chemistry reactivity is most important for the compound which a chemical substance undergoes a chemical reaction, either by itself or with other materials, with a complete release of energy.
The chemical reactions of a single substance or the chemical reactions of two or more substances that interact with each other and the efficient study of sets of reactions of these two categories method that applies to the study of reactivity of chemicals of all kinds’ experimental techniques that are used to observe these procedures. Theories to expect and to explanation for these methods. The chemical reactivity of a single substance covers its behaviour.
- Chemical composition
- Reactive intermediates
- Carbon anions and carbon cation
- Electrophiles and nucleophiles
Physical chemistry is the study of behaviour of the molecule and particular phenomena in chemical systems. In terms of principles and concepts of physics such as motion, energy, force, time, thermodynamics, quantum chemistry, statistical mechanics, analytical dynamics and chemical equilibrium. Physical chemistry in contrast to chemical physics is predominantly a macroscopic or supra-molecular science, as the majority of the principles on which it was founded relate to the bulk rather than the molecular/atomic structure alone.
Computational Chemistry is a branch of chemistry that is used to solve chemical problems. It uses the methods of theoretical chemistry, incorporated into efficient computer programs. To calculate the structures and properties of molecules and solids it is necessary.
- Conformational analysis
- Non-covalent interactions
- Acid-base chemistry
- Quantum chemistry
- Spectroscopy and crystallography
Track 8: Inorganic and Bioinorganic Chemistry
Inorganic chemistry is concerned with the synthesis and behaviour of inorganic and organometallic compounds. This field covers all chemical compounds except carbon-based compounds, which are the subjects of organic chemistry. Inorganic chemistry has applications in every aspect of the chemical industry, including, materials science, catalysis, surfactants, medications, fuels, pigments and agriculture.
Bioinorganic chemistry is a field that explains the role of metals in biology. Bioinorganic chemistry includes the study of both natural phenomena and as well as artificially introduced metals. Those are the non-essential in medicine and toxicology. Many biological processes depend upon molecules that fall within the realm of inorganic chemistry.
- Oxygen transport and activation proteins
- Metal ion transport and storage
- Bio mineralization
- Alkali and alkaline earth metals
Track 9: Medicinal Chemistry
Medicinal chemistry and pharmaceutical chemistry are disciplines at the intersection of chemistry, especially synthetic organic chemistry, and pharmacology and various other biological specialties, where they are included with plan, compound amalgamation and advancement for market of pharmaceutical specialists, or bio-dynamic atoms (drugs).
Substances utilized as prescriptions are frequently organic compounds, which are regularly isolated into the wide classes of organic compounds (e.g., atorvastatin, fluticasone, clopidogrel) and "biologics" (infliximab, erythropoietin, insulin glargine), the last of which are regularly restorative arrangements of proteins (normal and recombinant antibodies, hormones, and so on.). Inorganic and organometallic compounds are additionally valuable as medications (e.g., lithium and platinum-based operators, for example, lithium carbonate and cis-platin and also gallium).
Types and characterization of organic compounds
Industrial chemical testing and regulatory services to help quality and regulatory standards and optimal efficiency across the supply chain. Industrial Chemistry is the branch of chemistry, applies physical and chemical processes of conversion of raw materials into products that are of useful for mankind. Industrial chemistry is the manufacturing art for the transformation of waste matter into useful materials.
Track 11: Pharmaceutical Chemistry
Pharmaceutical chemistry is the study of drugs, and it involves development of drugs. This includes drug discovery, introduction, absorption, metabolism, and more. Pharmaceutical chemistry incorporates treatments and remedies for disease, analytical techniques, pharmacology, metabolism, quality assurance, and drug chemistry. Pharmaceutics deals with the formulation of an unadulterated drug substance into a dosage form.
Divisions of pharmaceutics include:
Unadulterated drug substances are generally white crystalline or amorphous powders. The clinical act of drugs depends on their form of presentation to the patient.
- Pharmaceutical chemistry and novel aspects
- Nano medicine and nanotechnology
- Pharmaceutical biotechnology and tissue culture
- Overview on pharmaceutical industry
- Pharmaceutical analysis
- Drug delivery techniques ,drug discovery and development
- Drug designing methodologies
Track12: Organic Photochemistry
Photochemistry is the branch of science deals with the effects of light. This term is utilized to depict a mixture reaction produced by absorption of light (wavelength from 100 to 400 nm) observable light (400 – 750 nm) or infrared radiation (750 – 2500 nm) in nature. Photochemistry is of enormous significance as it is the premises of photosynthesis, vision, and the development of vitamin D with sunlight. A photochemical reaction continues uniquely in contrast to temperature-determined reactions. Photochemical techniques get to high energy intermediates that can't be created thermally, vigour interference in a brief time frame, and permitting reactions generally difficult to reach by warm procedures. Photochemistry is likewise destruction, as shown by the photo-degradation of plastics.
- Organic and organometallic photochemistry
- Mechanistic organic photochemistry
- Synthetic organic photochemistry
Track 13: Electro Organic Chemistry
Electrochemistry is the part of chemistry deals with the inter-relation of electrical and chemical changes that are caused by the flow of current. Electrochemistry is a multidisciplinary branch which enables to deal with several fields within the physical, chemical and biological sciences.
- Bio electrochemical systems
- Molecular electrochemistry
- Synthetic electrochemistry
- Protein electrochemistry
Track 14: Fluorescent Molecules and Dyes
Fluorescent molecules, also called fluorophores or simply flour’s, respond distinctly to light compared to other molecules. As shown below, a photon of excitation light is absorbed by an electron of a fluorescent particle, which raises the energy level of the electron to an excited state. Fluorescent dyes are non-protein molecules. They are often used in the fluorescent labelling of biomolecules and can be smaller or more photostable than fluorescent proteins but cannot be genetically encoded.
- Reactivity and conjugated dyes
- Nucleic acid dyes
- Cell function dyes
- Uses outside the life proteins
The biological and chemical properties of natural products for the past two centuries has produced drugs for the treatment of several diseases, But has instigated the development of synthetic organic chemistry and the medicinal chemistry as a major route to discover efficacious and novel therapeutic agents. Nature provided a fascinating array of chemical structures in the form of bioactive secondary metabolite.
Heterocyclic chemistry is the branch of organic chemistry dealing with properties, and applications of these heterocyclic. Although heterocyclic compounds are inorganic most of the atoms contain at least one carbon atom. While the atoms are neither carbon nor hydrogen are normally referred to in organic chemistry as heteroatoms.
- Chemistry and efficacy of natural products
- Safety and regulation of natural products
- Health and beauty product innovation
- Methodologies for natural products
Analytical chemistry is the branch of science of obtaining, processing, and providing information about the composition and structure of matter. In other words, it is the art of determining what matter is present and if present then, how much of it exists. Analytical chemistry is often described as the branch of chemistry responsible for characterizing the composition of matter, both qualitatively and quantitatively.
An understanding of attraction dipoles and also the numerous types of non-covalent unit forces permits America to elucidate on a molecular level and many evident physical properties of organic compounds. Throughout this section, we square measure progressing to specialize in solubility, melting point and boiling purpose. Boiling happens once the chance of heat turning into internal energy and work to carry out vaporization becomes up to the chance of the reverse pathway. The boiling thermal property is higher the stronger the unit attractions as a results of the stronger the static force of attraction, the ton of energy is required to separate the particles and the larger the static P.E. increase associated with vaporization.
- Principles of molecular spectroscopy and electromagnetic radiation
- Infrared spectroscopy
- Mass spectroscopy
- Uv vs abdorption spectroscopy
- NMR spectroscopy
- Molecular spectroscopy
Track 17: Organometallic Polymers
Chemical reactions occur once collisions occur between atoms or molecules and there is ensuing modification among the arrangement of the chemical bonds. Therefore the rate of a reaction is proportional to the number of collisions between molecules. Not every collision will cause a reaction of the complete variety of collisions solely a specific share will occur at the appropriate energy to allow the processes of force breaking and forming to occur. A first-order reaction could also be a reaction that yields at a rate that depends linearly on only one analysis. Differential rate laws square measure usually accustomed describe what is occurring on a molecular level throughout a reaction whereas integrated rate laws square measure used for crucial the reaction order and also value of the speed constant from experimental measurements and chemical biology.
- Synthesis of polymers
- Properties of polymers
- Structure and morphology
- Phase behaviour
- Chemical and optical properties
Track 18: Biochemical Interactions
Drug interaction is the change in the action or side effects of a drug caused due to administration with a food. There are many causes of drug interactions for example one drug may alter the pharmacokinetics of another drug alternatively.
The interactions may result from competition for a single receptor or signalling pathway. The risk of a drug-drug interaction increases with the usage of drugs. Over a third (36%) of the elders regularly uses five or more medications and 15% are at risk of a significant drug-drug interaction.
- Pharmacodynamic interactions
- Pharmacokinetic interaction
- Herb-drug interaction
- Underlying factors
Track 19: Biochemistry and Agricultural Chemistry
Biochemistry also called as biological chemistry, it is the study of chemical processes relating to living organisms Agricultural chemistry is the study of Biochemistry and mostly organic chemistry which are vital in agricultural production. The processing of raw products into foods and beverages in environmental monitoring and hazardous rectification. These studies emphasize the relationships between plants, animals and microorganism and their environment. The science of chemical compositions and changes concerned within the production, protection and use of crops and placental. All the life process through those humans acquire food and fibre for themselves and feed for their animals. As an engineering or technology it's directed towards management of these processes to extend yields, improve quality and cut back prices.
- Biochemistry and agrochemicals
- Elementary calculus
- Weed biology and control
- Biochemistry and metabolism
Track 20: Green and Environmental Chemistry
Green chemistry is also known as sustainable chemistry. It is the branch of chemistry and chemical engineering focused on the creations of products and processes that minimize the use and protect the generations from hazardous substances.
Environmental chemistry focuses on the consequences of chemical polluting on nature. Environmental chemistry focuses on technological approach preventing pollution and reducing consumption of non-renewable resources.
It is our delight to welcome you to the “5th International Conference on Organic Chemistry” on April 25-26 2022, Webinar with the theme "Focusing on advanced methodologies and techniques in Organic Chemistry". This congress will be a great platform for research scientists and young researchers to share their recent findings in this field of Chemistry and this Conference includes multiple opportunities for each and every speaker and participants.
The significant growth in demand for fertilizer in the farming sector and increasing use of explosives in mining industries is expected to drive the demand. The organic acids market is estimated to grow at a CAGR of 5.48% from 2017 to 2022, to reach a projected value of USD 11.39 Billion by 2022. The Key participants in the supply chain of the organic acids market are the raw material suppliers, end use industries and product manufacturers. Global organic chemicals market is expected to be driven by growing industrialization and rapid urbanization over the forecast period. The Latin America magnesium nitrate market size was estimated at USD 78.3 million in 2018 and is expected to grow at a CAGR of 4.5% over the forecast period.
The international microcellular polyurethane foam market was valued at $ 5.06 Billion in 2015, and reached $ 6.95 Billion by 2021 at a CAGR of 5.5% between 2016 and 2021 the high density foam reports the largest share in the microcellular polyurethane foam market. It is projected to be the swiftly growing type of the microcellular polyurethane foam market between 2016 and 2021.
The research will provide a forecast for Global Chemical fiber Lubricant market till 2022. The report is very important for anyone involved in the Global Chemical fiber Lubricant industry. The study gives a brief outlook of the entire, markets. New vendors in the market are facing tough competition from established international vendors as they struggle with reliability, technological innovations and quality issues. The report will answer questions about the current market developments and the scope of competition, opportunity cost anymore.
Global Chemical Fiber Lubricant market, the research report includes diverse topics like total market size, key market drivers, challenges, growth opportunities, key players, etc. We have also covered Lead market updates, technological updates and the impact of regulations .New start-ups entering the space of Global Chemical fiber Lubricant need to attentively pick their niches and genres so that they can compete on an equal grip with global companies who have an end to end development studios, global skills, production capabilities and experience backing them.
The global chemical industry has seen a 7 percent annual growth rate, around €3.4 trillion in 2010. Major growth rate in the past has driven by Asia, by which it owns nearly half of global chemical market. A 3 percent growth rate in global market is expected in the next few years, where Asian countries are expected to own two-thirds of the market by 2030.
Whereas Organic chemical industry composed to hold 51% of global chemical market by 2030. A 10% growth rate has been seen in Organic Chemistry market in the last 5years in Latin America, North America, Europe, and Asia Pacific. Extensive primary research is being conducted among Leading companies such as Dow Chemicals, SABIC, BASF, DuPont and Sinopec Chemicals are majorly focussing on Primary Research
Figure 1: Country-wise Organic Exporters
In 2016, Global Market of Organic Acids has raised to $17,837 million and an increase is expected up to $29,977 million by the end of 2023, influencing a CAGR of 9.3% from 2017 to 2023.
Many advanced researches are being carried out with huge investments in R & D by popular chemical industries like Cargill, Inc., Henan Jindan Lactic Acid Technology Co. Ltd., Myriant Corporation, The Dow Chemical Company, BASF SE, Eastman Chemical Company, Tate & Lyle Plc., Celanese Corporation, Archer Daniels Midland Company, and E. I. Du Pont De Nemours to develop advanced methodologies to meet global needs.
Every year a noticeable increase in Chemical production is seen with an expected growth of 2.7% by the end of 2019, The largest chemical market in the world – China – has marked a significant growth rate globally. Forecasts expect a growth of 3.6 % of Chemical production in China, which creates a slight weaker environment still accounting 60% global chemical growth
General Market Analysis :
Raw materials in pricing
Caprolactam, polystyrene, acetic acid, adipic acid, vinyl acetate - are the major raw materials in organic Chemistry. The cost of these raw materials are being steadily maintained decreasing the fluctuations in pricing thus decreasing the finished good price and hence increasing the competition in raw material market. The eventual processing has resulted a negative mark despite the stable market of raw materials.
The main consumers of raw materials are the USA, Western Europe, China. This fact is due to a large number of plants for the processing of adipic acid and caprolactam are based in these regions. These regions also have facilities for the production of cyclohexane, which is a semi product for the production of caprolactam and adipic acid. European textile fiber manufacturers are gradually losing their market share, failing to compete with products from Asia (mainly from China, Taiwan and lately from Indonesia and Vietnam), where labor costs are much lower and the quality control is constantly growing, imitating western technologies. The Asian region with China in the lead, is a rapidly growing market for adipic acid (an average annual growth of 5.3% up to 2017). It's growth is stimulated by the ever growing consumption of this chemical in the urethane industry of China. The availability of benzene in the European region is growing, and the price is going down affected by the oil quotes decline.
- American Institute of Chemists (AIC)
- American Society for Mass Spectrometry
- American Society of Brewing Chemists
- British Mass Spectroscopic Society
- American Association for Clinical Chemistry
- European Society for Separation Science
- The Israeli Society for Mass Spectrometry – ISMS
- Royal Society of Chemistry (RSC)
- The Chromatographic Society
- Swedish Mass Spectrometry Society
- Italian Chemical Society
- American Chemical Society
- Spanish Royal Society of Chemistry
- University of California, Berkeley
- University of Tokyo
- Georgia Institute of Technology
- University of Texas at Austin
- University of California, Irvine
- University of Michigan, Ann Arbor
- Kyoto University
- University of Pennsylvania
- University of California, Los Angeles
- Northwestern University
- Massachusetts Institute of Technology
- Swiss Federal Institute of Technology, Zurich
- Cambridge University
- Harvard University
- Stanford University
- Yale University
- Columbia University
- Cornell University
- Technical University, Munich
- UniveOxfordrsity of
- University of Strasbourg
- University of California, San Diego
- Heidelberg University
- University of Toronto
- Organic Chemistry
- Bioorganic Chemistry
- Catalysis of Organic Compounds
- Organic Synthesis and Chemical Bonding
- Structure and Reactivity of Organic Compounds
- Physical and Computational Organic Chemistry
- Inorganic and Bioinorganic Chemistry
- Medicinal Chemistry
- Industrial Chemistry
- Pharmaceutical Chemistry
- Organic Photochemistry
- Electro Organic Chemistry
- Fluorescent Molecules and Dyes
- Natural Products and Heterocyclic Chemistry
- Analytical Techniques in Organic Chemistry
- Organometallic Polymers
- Biochemical Interactions
- Biochemistry and Agricultural Chemistry
- Green and Environmental Chemistry
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