Call for Abstract

2ndAnnual Congress on Polymer and Materials Chemistry , will be organized around the theme “Pragmatic impacts of polymers and materials in human daily life”

Chemistry 2019 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Chemistry 2019

Submit your abstract to any of the mentioned tracks.

Register now for the conference by choosing an appropriate package suitable to you.

Organic Chemistry is a sub-discipline of chemistry which involves the study of structure, characteristics, properties, reactions of organic compounds (the molecules or compounds containing carbon atoms). The study of chemical reactions of organic molecules is important to examine their use in the synthesis of polymers, drugs and other target molecules. Organic Chemistry involves the study of various elements and chemicals classified based on the periodic table. The study also overlaps with Bio chemistry, Polymer Chemistry, Medicinal Chemistry and Material Science.


  • Track 1-1Biomolecules
  • Track 1-2Hydrocarbons
  • Track 1-3Aromatic compounds

Natural polymers are produced by living organisms and are also known as “Biomolecules” which have a well-defined structure consisting of monomeric units. Proteins and nucleic acids found in human body are natural polymers. Most natural polymers are condensation polymers formed from monomers. Cellulose, the main structural component of plants is another natural polymer. Natural polymers apart from playing an important role in life processes of living organisms, has now been used in Nano-drug delivery.


  • Track 2-1Polypeptides
  • Track 2-2Polynucleotides
  • Track 2-3Polysaccharides

Synthetic polymers are made by the scientists through various chemical processes as a result of extensive research to improve natural polymers. Synthetic polymers are classified as thermosets, thermoplastics, elastomers, synthetic fibers based on their utility. These polymers are hard as well as flexible and can be molded to any shapes and structures to fit their needs.


  • Track 3-1Rubber
  • Track 3-2Copolymers
  • Track 3-3Homopolymers
  • Track 3-4Silicones

Chemistry accompanied with the knowledge of polymers paves way for a wide range of research and developments in various areas of science. Starting from biochemistry to diagnostics, various researches in the field of analytical chemistry, chemical biology and supramolecular chemistry led to many useful applications of polymer science.


  • Track 4-1Electrochemistry
  • Track 4-2Chemical Kinetics
  • Track 4-3Metallurgy

Analytical polymer science explains the application of analytical techniques for the study of polymers. The use of instruments and devices to identify, separate and quantify the synthetic polymers, especially the elastomers popularly called as rubber is dealt well under this topic. Analytical techniques help the scientists to understand the polymers in a molecular level which aids in developing specific characteristics in the new polymer.


  • Track 5-1Coordination Polymers
  • Track 5-2Supercritical fluids (SCFs)
  • Track 5-3Anti-biofouling polymer
  • Track 5-4Antimicrobial polymer resin

Polymers play an important role in the field of medicine particularly in producing disposable implants, devices used in prosthetic surgery, dentistry, etc., The polymers are thus modified to interact safely with the living tissues to serve the medical purpose without any interventions. They are synthesized in such a way that they have a good compatibility under various physical and chemical conditions. 


  • Track 6-1Stents
  • Track 6-2Blood Substitutes
  • Track 6-3Prosthesis

Polymers possess several properties among which light weight, corrosion-resistance, and ease of manufacture makes them an ideal choice for making load-bearing polymeric matrix composites, special coatings for signature control, coatings for corrosion reduction in waste-holding tanks, fuel storage tanks, and metal pipe linings, hoses, gaskets, pipelines that are used in navy. The required performance is achieved when polymers meet the proper technology.


  • Track 7-1Fiber reinforced composites (FRP)
  • Track 7-2RADAR Domes
  • Track 7-3Rheology

Tissue engineering serves to be the focus of research for regenerative medicine as they create the potential for new treatments for various diseases. The designing of scaffolds using polymers gains importance as scaffolds play a unique role in tissue regeneration and repair. The properties of polymer and the design of scaffold has a great impact on the function of incorporated cells as well as the host tissue.


  • Track 8-1Regenerative medicine
  • Track 8-2Stem Cell Biology
  • Track 8-3Transplantation

The various approaches, formulations, technologies, and systems involved in transporting a pharmaceutical compound in the body as per the need to safely achieve the desired therapeutic effect comes under drug delivery systems. The use of polymers for drug delivery has been proved to be the “intelligent” delivery systems, because smart polymers can release the drug at the appropriate time and site of action.


  • Track 9-1Smart polymers
  • Track 9-2Recognitive polymers
  • Track 9-3Glucose responsive polymers

Polymers apart from being used in biotechnology, medicinal applications have now strengthened its applications in the field of information and communication. Polymers provide the ease of manufacture along with tough and durable mechanical properties. The electrical and mechanical properties of the polymers made them the material of choice for most communication cables, inside wires, insulators and packaging.


  • Track 10-1Nanofibers
  • Track 10-2Seasickness patches
  • Track 10-3Polymer Dielectrics

Number of techniques are available for the 3D printing of polymers. This technique creates parts by sintering fine polymer powder particles, to fuse them together locally. Using this technology, larger parts can be made according to the needs with required properties along with increased efficiency. Prototyping can be made easy using 3D printing with polymers at low cost and the finish can be made in different variants.


  • Track 11-1FDM technology
  • Track 11-2Hybrid printing materials
  • Track 11-3Stereolithography (SLA)
  • Track 11-4Poly Jet technology

The study of physical and chemical behavior of metals and their mixtures called as alloys comes under metallurgy and it is an important domain of materials science and engineering. Though most percentage of world’s metal production is based on iron, other metals are also given importance in metallurgy as this particularly deals with the extraction of all metals from their ores and its production.


  • Track 12-1Alloys
  • Track 12-2Ferrous metallurgy
  • Track 12-3Non-ferrous metallurgy

Ceramic science is the technology that create objects from inorganic, non-metallic materials which is done by the action of heat. This can also be done at lower temperatures using precipitation reactions from high-purity chemical solutions. This is a broad term which includes the purification of raw materials, production of chemical compounds and their formation into components followed by the study of their structure, composition and properties.


  • Track 13-1Glass ceramics
  • Track 13-2Ceramic composites
  • Track 13-3Biomaterials

Solid state chemistry is also known as materials chemistry which is the study of synthesis, structure and properties of solid phase materials. The synthesis of novel metals comes under solid state chemistry which also relates various subjects like solid state physics, materials science, electronics, etc., Solid state chemistry finds its importance in discovering new thermoelectric materials wherein high electronic conductivity, high thermoelectric power, and low thermal conductivity should be incorporated in the same solid simultaneously.


  • Track 14-1Mineralogy
  • Track 14-2Thermodynamics
  • Track 14-3Crystallography

As the properties of materials such as polymers, plastics, metals, alloys used in various applications impact their performance, these materials have to be analyzed before use so as to ensure whether they satisfy its intended purpose. The evaluation of materials is done to avoid contamination and to improve the quality of the metals.


  • Track 15-1Chromatography
  • Track 15-2Mass Spectrometry
  • Track 15-3NMR Analysis

Instrumentation plays an important role in the research of materials as they help us to relate the composition, structure, and properties of the materials to its performance for a desired application with greater sensitivity and quantitative resolution. Nowadays, instrumentation for materials research often involves computational methods and computer simulated measurement tools.


  • Track 16-1Neutron scattering
  • Track 16-2Microscopy
  • Track 16-3Spectroscopy
  • Track 16-4ESCA (Electron Spectroscopy for Chemical Analysis)

The equipment for industries, defense research widely uses many advanced materials such as thin films, semiconductors, metal matrix, etc., that are made by modifying the existing materials to obtain improved performance suitable for the application. These materials exhibit completely novel properties and are used mainly in information storage devices. The areas where advanced materials are of great use include energy storage, supercapacitors, flexible electronics, sensors, electro-magnetic shielding, communication, special optical fibers, polymers for photonics, displays etc.


  • Track 17-1Robots
  • Track 17-2Nuclear plants
  • Track 17-3Missile

The emergence of nano-materials has made materials science to play an important role in sustainable technologies for energy conversion, storage and savings. Principal areas of interest are solar cells, batteries, fuel cells, thermoelectrics, more efficient lighting and hydrogen technologies. The modelling of nano-materials maintains a balance between durability, efficiency and costs thereby proving to be instrumental in developing energy efficient devices to meet the future needs.


  • Track 18-1Polymer electrolytes
  • Track 18-2Nano structured super conductors
  • Track 18-3Sun rechargeable smart cards
  • Track 18-4Electrocatalysts

Certain inevitable challenges are to be faced by the field of material science before developing new materials with desired multifunctional properties to protect the environment. The nuclear sector must investigate the materials in depth to deal with the radiation. The safety requirements increase the demand for better control of the ageing of materials, structures and components.


  • Track 19-1Hybrid materials
  • Track 19-2Multifunctional materials
  • Track 19-3Smart materials

The process of influencing and manipulating composition and properties of materials at the atomic level have led to many innovations that enhances various fields of science and technology. The innovations mainly aim at recycling and reuse of materials amidst the challenges underlying to link the nano-scale and large scale together to support a circular economy.


  • Track 20-1Bio-receptive concrete
  • Track 20-2Tracking systems