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Euro Organic Chemistry 2018, will be organized around the theme “Tackling the scientific challenges and bridging excellence of new era in Organic Chemistry”

Euro Organic Chemistry 2018 is comprised of 19 tracks and 112 sessions designed to offer comprehensive sessions that address current issues in Euro Organic Chemistry 2018.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

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Organic molecules contain carbon atoms. The carbon atoms area unit covalently bonded to different atoms and numerous chains of carbon atoms is found in most each molecule. Carbon has four valence electrons and so can create four bonds in accordance with the octet rule. All non-carbon-to-carbon bonds are going to be assumed to be carbon-hydrogen bonds as atomic number 1 atoms area unit the foremost ordinarily found hooked up atom. Atomic number 1 has one negatron and can create one chemical bond. The atom is capable of constructing single, double and triple bonds furthermore as bonding with chemical element nitrogen, chlorine or bromine. Chemical element has six valence electrons, and can create 2 valence bonds. One bond and a covalent bond area unit each potential for chemical element atoms. Gas has 5 valence electrons and can create 3 valence bonds. Single, double and triple bonds area unit all potentialities for gas atoms.

  • Track 1-1Types and characterization of organic compounds
  • Track 1-2Functional groups
  • Track 1-3Aliphatic and aromatic compounds
  • Track 1-4Heterocyclic compounds
  • Track 1-5Nomenclature of new compounds

Inorganic chemistry  mainly deals with the synthesis and behavior of inorganic and organometallic compounds. This field covers all chemical compounds except the myriad organic compounds . The difference between the two disciplines is far from absolute, as there is much intersection in the subdiscipline of organometallic chemistry. It has applications in every aspect of the chemical industry, including catalysis, materials science, pigments, surfactants, coatings, medications, fuels, and agriculture.

Structure determination is also a procedure by that the three-dimensional atomic coordinates of a molecule or biomolecule area unit resolved exploitation associate analytical technique. Many techniques square measure utilized in structure determination, most generally X-ray physics, nucleon magnetic resonance spectrometry, microscopy and molecular modelling. Nuclear resonance is associate degree analytical chemistry technique utilized in control and analysis for determinative the content and purity of a sample in addition as its molecular structure. NMR could also be used to verify molecular conformation in answer in addition as checking out physical properties at the molecular level like conformational activity, half changes, solubility and diffusion. Elemental analysis could also be a way where a sample of some material is analysed for its elemental and generally atom composition. Mass  is associate degree analytical chemistry technique that helps confirm the quantity and type of chemistry gift throughout a sample by live the mass-to-charge quantitative relation and abundance of gas-phase ions. A prism spectrographic analysis determines the mass of a molecule by live the mass-to-charge magnitude relation of its particle diffusion. Ions square measure generated by causation either the loss or gain of a charge from a neutral species.

  • Track 2-1Organometallic nomenclature
  • Track 2-2Carbonmetal Bonds in organometallic compounds
  • Track 2-3Grignard reagents
  • Track 2-4Transition metal organometallic compounds
  • Track 2-5Carbenes and carbenoids

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. Every ester has 3 components: a 5-carbon sugar, a phosphate cluster and a element base. If the sugar is carbohydrate the polymer is polymer. 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 chemistryamino 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. They include the 23 proteinogenic (protein-building) amino acids that mix into peptide chains (polypeptides) to form the building-blocks of a vast array of proteins.

  • Track 3-1Peptides sequence analysis
  • Track 3-2Classification of amino acids
  • Track 3-3Stereochemistry of amino acids
  • Track 3-4AcidBase behaviour of amino acids
  • Track 3-5Synthesis of amino acids
  • Track 3-6Reactions of amino acids
  • Track 3-7Peptide structure amino acid Analysis
  • Track 3-8Nucleosides

Carbohydrates perform varied roles in living organisms. Polysaccharides serve for the storage of energy (e.g. starch and glycogen) and as structural components (e.g. cellulose in plants and polysaccharide in arthropods). The 5-carbon monosaccharose saccharide is an important part of coenzymes (e.g. ATP, furor and NAD) and also the backbone of the genetic molecule called RNA. The connected deoxyribose may be a part of polymer. Saccharides and their derivatives include several alternative necessary biomolecules that play key roles within the system and fertilization preventing pathologic process, coagulation and development. The term is most common in organic chemistry wherever it's a equivalent word of sugar, a group that has sugars, starch, and polyose. The saccharides are divided into four chemical groups: monosaccharides, disaccharides, oligosaccharides and polysaccharides. In general, the monosaccharides and disaccharides that are smaller (lower molecular weight) carbohydrates are commonly said as sugars.

  • Track 4-1Classification of carbohydrates
  • Track 4-2Fischer projections and the DL notational system
  • Track 4-3Aldotetroses
  • Track 4-4Aldopentoses and aldohexoses
  • Track 4-5Mutarotation
  • Track 4-6Ketoses
  • Track 4-7Glycosides
  • Track 4-8Disaccharides and polysaccharides
  • Track 4-9Epimerization and isomerizations

The study of stereochemistry focuses on stereoisomers and spans the complete spectrum of organicinorganic, biological, physical and particularly supra molecular chemistry. Stereochemistry includes strategies for determinant and describing these relationships; the result on the physical or biological properties these relationships impart upon the molecules in question, and also the manner during which these relationships influence the reactivity of the molecules.

  • Track 5-1Molecular chirality and enantiomers
  • Track 5-2Properties of chiral molecules and optical activity
  • Track 5-3The cahnIngoldPrelog RS notational system
  • Track 5-4Physical properties of enantiomers
  • Track 5-5Stereogenic center

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. Ion-Ion forces or attractions area unit the strongest. They involve the attraction between species bearing a minimum of a full charge and a species bearing a minimum of a full charge.

  • Track 6-1Principles of molecular spectroscopy electromagnetic radiation
  • Track 6-2Patterns of spinspin splitting pairs of doublets
  • Track 6-3Infrared spectroscopy
  • Track 6-4Mass spectrometry
  • Track 6-5 UV Vis Absorption Spectroscopy
  • Track 6-6Molecular Spectroscopy
  • Track 6-7NMR Spectroscopy
  • Track 6-8Chromatography

Carboxylic acids are ordinarily named as though seldom used,. IUPAC-recommended names also exist. For instance, butanoic acid (C3H7CO2H) is in keeping with IUPAC tips additionally called butyric acid. To more simply understand abundant of the below discussion of reactions involving carboxyl acids it may be useful to note that the radical itself could be a "hydroxylated carbonyl group" which means that 2 of the carbon atoms four bonds area unit to associate degree atomic number 8 atom, the carbon atom's third bond is to a second atomic number 8 atom (whose different bond is to a element atom) and also the carbon atom's fourth bond attaches to R. A atom double bonded to associate degree atomic number 8 atom could be a carbonyl group and two of the carbon atom's bonds stay available for bonding.

  • Track 7-1Carboxylic acid nomenclature
  • Track 7-2Sources of carboxylic acids
  • Track 7-3Reactions of carboxylic acids
  • Track 7-4Carboxylic acid derivatives
  • Track 7-5Sources of esters
  • Track 7-6Preparation of amides
  • Track 7-7Preparation of nitriles

Organic molecules are described additional ordinarily by 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 for ionic bonding one molecule cannot fully describe the bonding that takes place between shut atoms relative to the empirical data for the actual bond lengths between those atoms. Organic reactions are chemical reactions involving organic compounds.

  • Track 8-1Atoms, electrons and orbitals
  • Track 8-2Ionic bonds
  • Track 8-3Resonance
  • Track 8-4Molecular orbitals of the hydrogen molecule
  • Track 8-5Polar covalent bonds and multiple bonding

Chemoinformatics is that the commixture of these information resources to transform information into info data and data into knowledge for the supposed purpose of constructing higher selections faster within the space of drug lead identification and optimisation. These in silico techniques are employed in as an example pharmaceutical companies within the method of drug discovery. These ways may be employed in chemical and allied industries in varied different forms. Cheminformatics may be applied to information analysis for varied industries like paper and pulp and dyes and such allied industries. Chemical information will pertain to real or virtual molecules.

  • Track 9-1Chemoinformatics and its applications
  • Track 9-2Cheminformatics tools for drug discovery
  • Track 9-3Quantitative structure activity relationship
  • Track 9-4Computational chemistry
  • Track 9-5Bioinformatics

Green chemistry, also referred to as property chemistry is a part of chemistry and chemical engineering targeted on the planning of products and processes that minimize the utilization and generation of hazardous substances. Environmental chemistry focuses on the consequences of polluting chemicals on nature inexperienced chemistry focuses on technological approaches preventing pollution and reducing consumption of unrenewable resources. Green chemistry overlaps with all subdisciplines of chemistry however with a specific target chemical synthesis, method chemistry and chemical engineering in industrial applications. To a lesser extent the principles of green chemistry conjointly affect laboratory practices.

  • Track 10-1Green catalysis
  • Track 10-2Green chemical solvents
  • Track 10-3New trends in green chemistry
  • Track 10-4Chemical risk and regulatory issues
  • Track 10-5Human exposure and toxicity

Electroorganic synthesis mostly used in organic reactions is possibly the famous Kolbe electrolysis, there is no other significant synthesis have been found till the reductive dimerization of acrylonitrile to adipo­ nitrile was developed by Dr. M. M. Baizer of Monsanto Co. The electroorganic chemistry has been studied widely with the prospects that it is a new useful tool for finding new Synthesis in organic reactions.


Electrochemical reactions of organic compounds to show that the electro organic chemistry is useful in organic synthesis, electroorganic chemistry covers a great variety of reactions, with their applications in organic synthesis.  and also some entrenched processes such as the Kolbe electrolysis, pinacolic coupling, and hydrodimerization.

  • Track 11-1Bioelectrochemical systems
  • Track 11-2Electroorganic Reactions
  • Track 11-3Electroorganic Reactions
  • Track 11-4Molecular Electrochemistry
  • Track 11-5Synthetic Electrochemistry
  • Track 11-6Protein Electrochemistry
  • Track 11-7Biosensors
  • Track 11-8 Redox Flow Batteries

Chemical reactions occur once collisions occur between atoms or molecules and there is ensuing modification among the arrangement of the chemical bonds. Therefore 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 the value of the speed constant from experimental measurements and chemical biology.

  • Track 12-1Polymer structure and morphology
  • Track 12-2Polymer synthesis and polymer coating
  • Track 12-3Enzyme kinetics and thermodynamics of enzymatic reactions

Agricultural chemistry is the study of each chemistry and organic chemistry that are vital in agricultural production, the process of raw products into foods and beverages and in environmental monitoring and 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. As a basic science it embraces additionally to test-tube chemistry; all the life processes through that 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.

  • Track 13-1Biochemistry and agrochemicals
  • Track 13-2Elementarycalculus
  • Track 13-3Weed biology and control
  • Track 13-4Biochemistry and metabolism
  • Track 13-5Environmental management

Catalysed reactions have a lower energy (rate-limiting free energy of activation) 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, 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 action chemical action.

  • Track 14-1Heterogeneous catalytic process
  • Track 14-2Catalyst formulation and preparation methods
  • Track 14-3Catalysts characterization methods
  • Track 14-4Mechanism of catalytic reactions
  • Track 14-5Design of catalysts and simulation techniques

Physical chemistry is the study of the link between structure and reactivity of organic molecules. A lot of specifically, modern physical chemistry applies the experimental tools of chemistry to the study of the structure of organic molecules and provides a theoretical framework that interprets however structure influences each mechanisms and rates of organic reactions. It will be thought of as a subfield that bridges organic chemistry with physical chemistry. Physical organic chemists use each experimental and theoretical discipline like spectrum analysis, chemical analysis, natural philosophy and process chemistry and scientific theory to check each the rates of organic reactions and also the relative chemical stability of the beginning materials, transition states and product. Chemists during this field work to know the physical underpinnings of chemistry and thus physical chemistry applications in specialised areas as well as chemical compound chemistry, supramolecular chemistry, chemical science and chemical science.

  • Track 15-1Atomic theory
  • Track 15-2Biophysical Chemistry
  • Track 15-3Thermochemistry and quantum chemistry
  • Track 15-4Chemical bonding, aromaticity, anti and homoaromaticity and structures
  • Track 15-5Solvent effects and isotope effects on organic reactions
  • Track 15-6Acidity, nucleophilicity and electrophilicity
  • Track 15-7Equilibria

The investigation of biological and chemical properties of natural products for the past two centuries has not only produced drugs for the treatment of several diseases, but has instigated the development of synthetic organic chemistry and the arrival of medicinal chemistry as a major route to discover efficacious and novel therapeutic agents. Structural alteration of natural compounds or synthesis of novel compounds based on designs following a natural compound scaffolding have offered us a lot of vital new drugs in the fields of medicine, agriculture and food spheres. Nature has provided a fascinating array of chemical structures in the form of bioactive secondary metabolites.

  • Track 16-1Chemistry and efficacy of natural products
  • Track 16-2Safety and regulations on natural products
  • Track 16-3Cosmeceuticals, nutraceuticals (functional foods) and beverages
  • Track 16-4Health and beauty product development and innovation
  • Track 16-5Methodologies for natural products

In Flow chemistry a compound reaction is always running in a consistently streaming stream instead of in batch generation. At the end , pumps move liquid into a tube, and where tubes go along with each other, the liquids get in touch with each other. On the off chance that these liquids are receptive, a response happens. Stream science is an entrenched system for use at a vast scale when producing large amounts of a given material. In any case, the term has just been authored as of late for its application on a research center . Often, smaller scale reactors are utilized.

  • Track 17-1 Continuous flow reactors
  • Track 17-2 Photo chemistry in combination with flow chemistry
  • Track 17-3 Electrochemistry in combination with flow chemistry
  • Track 17-4Segmented flow chemistry

Photochemistry is the branch of science deals about the substance 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 premise of photosynthesis, vision, and the development of vitamin D with sunlight .Photochemical reactions continue 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 photodegradation of plastics.

  • Track 18-1Organic and Organometallic Photochemistry
  • Track 18-2Mechanistic organic photochemistry
  • Track 18-3Synthetic organic photochemistry

 Medicinal Chemistry and pharmaceutical science are disciplines at the conjunction of science, mainly  synthetic organic science, and pharmacology and different other organic claims to fame, 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).


Specially, restorative science in its most basic work on—concentrating on organic compounds —envelops manufactured organic chemistry and parts of common items and computational science in close blend with biological chemistry, enzymology and auxiliary science, together going for the disclosure and improvement of new helpful operators. Basically, it includes concoction parts of ID, and after that orderly, exhaustive engineered adjustment of new substance elements to make them reasonable for helpful utilize. It incorporates manufactured and computational parts of the investigation of existing medications and operators being developed in connection to their bioactivities (natural exercises and properties), i.e., understanding their structure-action connections (SAR). Pharmaceutical science is centered around quality parts of prescriptions and expects to guarantee wellness for motivation behind restorative products.


At the organic interface, restorative chemistry consolidates to shape an arrangement of exceedingly interdisciplinary sciences, setting its organic , physical, and computational accentuations nearby organic ranges, for example, organic chemistry, atomic science, pharmacognosy and pharmacology, toxicology and veterinary and human medication; these, with extend administration, insights, and pharmaceutical business rehearses, methodicallly shortest 

  • Track 19-1Pharmaceutical Sciences
  • Track 19-2Drug discovery
  • Track 19-3Pharmacophore and Xenobiotic metabolism
  • Track 19-4Pharmacognosy and Pharmacokinetics
  • Track 19-5Pharmaceutical Industry
  • Track 19-6Anticancer agents
  • Track 19-7Pharmacology and toxicology
  • Track 19-8CADD (Computer Aided Drug Design)
  • Track 19-9Drug Design and Drug Development
  • Track 19-10Hit to lead and lead optimization