Longdom proffers our immense pleasure and honor in extending you a warm invitation to attend Polymer Chemistry 2019. It is focusing on ‘Share Your Vision and developments in Biopolymer.’ to enhance and explore knowledge among Chemistry and Materials Science Departments and to establish corporations and exchanging ideas. Providing the right stage to present stimulating Keynote talks, Plenary sessions, Discussion Panels, B2B Meetings, Poster symposia, Video Presentations, and Workshops.
Track 1. Advanced characterization of polymers
Polymer characterization is the analytical branch of polymer science which includes determining molecular weight distribution, the molecular structure, the morphology of the polymer, thermal properties, mechanical properties, and any additives of Polymeric materials. Polymer characterization is done with a variety of experimental approaches.
Track 2. Structural and Functional Properties of Polymers
Mainly Polymers are composed of compounds of carbon, hydrogen and hydrocarbons. These are specifically made of carbon atoms bonded together, into long chains and one to the next other that are called the backbone of the polymer. Whereas the Functional polymers are those contains functional groups that have a greater polarity or reactivity than a classic hydrocarbon chain which improves their segregation, or reactivity.
Physical properties of a polymer such as its strength, flexibility, reactivity, Good corrosion resistance, lose dimensional tolerances, Poor tensile strength and transparency or in different colours depends on Chain length, Side groups, functional group attached and Cross-linking.
Track 3: Polymerization kinetics and mechanisms
Polymer synthesis, also called polymerization, polymer synthesis occurs via a variety of reaction mechanisms that vary in complexity due to functional groups present in reacting compounds and their inherent steric effects. Both synthetic and natural polymer are created via polymerization of many small molecules, known as monomers,
Coupling of monomers using their multiple bonds is known as addition polymerization coupling of monomers by reaction in which two molecules are covalently bonded to each other through loss of a water molecule is called as condensation polymerization
Track 4: Noval Applications of Polymers
Today, polymer are commonly used in thousands of products as plastics, elastomers, coating, and adhesive, no wonder polymer are found in everything from compact discs to high-tech aerospace application. Polymer testing, consultancy for plastics and additives with applications includes aerospace, electronics, packaging, automotive and medical devices.
Track 5 : Recent developments in Polymer Science and Engineering
Materials science and engineering, involves the discovery and design of new materials, with an emphasis on solids and scientific study of the properties and applications of materials of construction or manufacture (such as ceramics, metals, polymers, and composites). Materials science is also an important part of forensic engineering and failure analysis. In a broad sense, materials science involves studying the synthesis, processing, structure, properties and performance of materials. Properties of interest can be mechanical, electrical, magnetic, optical and quantum mechanical. The outcome of such a study can directly impact the society in which we live and work, by benefiting the industries involved in electronics, communications, medicine, transportation, manufacturing, recreation, energy and environment.
Track 6: Synthetic Polymers
Synthetic polymers are those which are human-made polymers. Synthetic polymers are those which consists of repeated structural units called as monomers. Synthetic polymers are sometimes referred as “plastics”, of which the well-known ones are nylon and polyethylene. There are various synthetic polymers developed so far such as Nylon, Polyvinyl Chloride, Low-Density Polyethylene Polypropylene.
Track 7: Natural Polymers
Natural polymers occur in nature and can be extracted, The human body contains many natural polymers, such as proteins and nucleic acids. Cellulose, another natural polymer some of the Natural polymers includes DNA and RNA, Natural polymers are very much significant in all the life processes of all the living organisms.
Track 8: Recent advancements in Biopolymers
Biopolymers are the types of polymers that are produced by living organisms. In other words they are also know as polymeric biomolecules. Biopolymers are generated from renewable sources and they are easily biodegradable because of the oxygen and nitrogen atoms originate in their structural backbone
It is a biodegradable chemical compound that is observed as the most organic compound in the ecosphere. Biopolymer are primarily divided into two types, one is produced from living organisms and another is obtained from renewable resources but require polymerization.
Track 9: Bio-Plastics and their Applications
Bio-plastics are a form of plastic derived from renewable biomass source, such as vegetable oil, corn-starch, potato-starch rather than fossil-fuel plastics which are derived from petroleum bio plastics are biodegradable materials that come from renewable sources and can be used to lessen the problem of plastic waste that is suffocating the planet and polluting the environment. Bio-plastics are made through different processes. Some use a microorganism to process base materials, such as vegetable oils, acids, cellulose, starches and alcohols. Bioplastics were mainly established in an effort to discovery a replacement for conventional plastics.
Track 11: Polymer Nanotechnology
Now we are at the beginning of new era of science that explores the behavior of material at their bottom, set new areas in technical applications of polymeric materials, and expose immense opportunities in the enactment and application of materials. Nanotechnology has currently acknowledged an exceptional interest of researchers, technology incubators and commercial organizations to step headfirst in introducing the materials containing nanocomposite structure and new performance standards.
Other areas include polymer-based biomaterials, nanoparticle drug delivery, layer-by-layer self-assembled polymer films, miniemulsion particles, imprint lithography, polymer blends, fuel cell electrode polymer bound catalysts, electrospun nanofibers, and Nano-composites
Track 12: Bio-catalysis and Biochemistry of Polymers
Proteins are linear polymers built of monomer units so-called amino acids. The construction of a vast array of macromolecules or polymer structure from a limited number of monomer building blocks is a recurring theme in biochemistry. The function of a protein is directly dependent on its three dimensional structure unusually, proteins spontaneously wrinkle up into three-dimensional structures that are determined by the sequence of amino acids in the protein polymer. Thus, proteins are the embodiment of the evolution from the one-dimensional world of arrangement to the three-dimensional world of molecules capable of diverse activities.
Proteins comprise of a wide range of functional groups. These functional groups include alcohols, carboxylic acids, thiols, thioethers, carboxamides, and variety of basic groups. For instance, the chemical reactivity associated with these groups is essential to the function of enzymes, the proteins that catalyse specific chemical reactions in biological systems
Track 16: Polymeric Material Chemistry and Science
Material physics mainly describes the physical properties of materials whereas Materials chemistry implicates the use of chemistry for the design and synthesis of materials with interesting or potentially useful physical characteristics, such as magnetic, optical, structural or catalytic properties. current fields which materials physicists work in include magnetic materials, electronic, optical, and novel materials and structures, quantum phenomena in materials, non-equilibrium physics, and soft condensed matter physics. Material chemistry and physics also include the characterization, processing, performance, properties and molecular-level understanding of the substances.
The traditional examples of materials are metals alloys, polymers, Composite material semiconductors, ceramics and glasses.