March 02-03, 2020
Rome, Italy
Dear Friends and Colleagues,
Welcome to Rome for the “World Congress on polymer Chemistry and Materials Engineering” for the study of smart Materials and polymer Chemistry.
We are delighted to ask you to join the international polymer Chemistry community in Rome, Italy from August 15-17, 2021.
Polymer Chemistry 2021 guarantees to be associate lingering event that may compile speakers and delegates from everywhere the globe.
We anticipate over 500 participants, as well as international leaders at the forefront of the discipline that may gift the foremost recent advances in basic polymer chemistry and smart material science.
We have organized scientific sessions around a range of relevant and cutting-edge themes and enclosed workshops and networking sessions to boost interactions.
This is a chance to be a part of a significant international polymer Chemistry conferences in Rome, one in all the foremost super countries in terms of scientific progress and smart materials specially.
Polymer Chemistry 2021 can provide a key networking and academic interface for colleagues from trade, university, health suppliers and independent analysis organizations to come back along.
Young investigators, clinicians, scientists, researchers, trade partners and policy advocates are all invited to attend. we glance forward to seeing you for associate exciting week of material Engineering discoveries and exchange.
Looking forward to seeing you in Rome, Italy.
Warmest Regards,
Polymer Chemistry 2021 | committee members
The focus is mainly on minimizing the hazards and maximizing the efficiency of any chemical choice. The conference also includes Keynote speeches by prominent personalities from around the globe in addition to both oral and poster presentations.
On behalf of Polymer Chemistry 2020, we are glad to invite contributions from the enthusiastic academicians, scientists to organize International Symposiums/Workshops that are both empirical and conceptual in exploring new dimensions of green chemistry challenges towards achieving the solutions.
Who should attend???
Research Institutes and Companies providing research products and services for the Higher Education Sector polymer scientists, technologists, Chancellors/Vice Chancellors/ Promoters / Directors / Principals / Chairpersons /Academicians / Senior Management / Administrative Heads & Decision makers of Universities /Higher Educational Institutions (Public & Private)Media… and many more
Why exhibit???
Branding and marketing opportunity Showcase opportunities available in your own market and encourage foreign universities to collaborate Opportunity to sign MoUs with Global Universities and Institutions which are interested in Global Market Opportunity to explore tie-ups for research, student and faculty exchange programs, twinning programs, etc.
With members from around the world focused on learning about Polymer Chemistry and techniques this is your best opportunity to reach the largest assemblage of participants from the Polymer Chemistry community. With members from around the world focused on learning about polymer chemistry and its advances this is your best opportunity to reach the largest assemblage of participants from the Polymer Chemistry community. Presentations meet with current and potential scientist with new discoveries in the Polymer Chemistry and receive name recognition at this 2-day event. World renowned speakers, the most recent techniques, developments, and the newest updates in polymer chemistry.
Speaker Presentations
Polymerisation is the chemical process of thousands of monomers joining together to form polymers or polymeric compound. Usually it takes thousands of monomers to make a single polymer. Addition polymerisation is the type of polymerisation reaction that occurs when you take the monomers and simply add them together. There are two basic types of polymerisation. They are step-growth polymerisation and chain-growth polymerisation
SESSION 02: RECENT ADVANCES IN POLYMER CHEMISTRY
Researchers working in chemical synthesis are under increasing pressure to discover and develop innovative pathways and robust chemical processes as quickly as possible. The scope of Polymer Chemistry extends from oligomers with only a few repeating units to very long chain polymers with thousands or millions of repeating units Polymerization and modification reactions can be employed to produce designer polymers as new materials with practically any desired properties.
SESSION 03: APPLICATION OF POLYMERS
Polymers is used in day to day life floor coverings, garbage disposal bags, and packaging are other polymer applications. Automobile parts, windshields for fighter planes, pipes, tanks, packing materials, insulation, wood substitutes, adhesives, matrix for composites, and elastomers are all polymer applications used in the industrial market. Each industry has standards relevant to polymer applications. Our polymer application engineers and scientists possess the specialist industry knowledge which can bring you the insight you need to solve problems, progress product development, ensure compliance and achieve a successful market launch for the industries.
SESSION 04: BIOPOLYMERS AND BIO-PLASTICS
Bio-polymers are polymers produced by living organisms; in alternative words, they are compound biomolecules. Bio-polymers provide an alternative to oil based plastics, as they are made up off plants, usually polymers of starch or polylactic acid (PLA). They are presently used for luggage bags, cutlery and plates, pens, clothing, credit cards, food packaging, agricultural films, teabags, occasional filters, diapers and napkins. Bio-plastics are plastics derived from renewable biomass sources, like vegetable fats and oils, corn starch, straw, woodchips, food waste, etc. Bio-plastics are not free of environmental impact, and the carbon emissions related to growing crops and changing these into the specified chemicals has to be taken into consideration.
SESSION 05: SYNTHETIC AND GREEN POLYMERS
Synthetic polymers are human-made polymers. Synthetic polymers are derived from crude oil, and created by scientists and engineers. Examples of synthetic polymers include nylon, polythene, polyester, Teflon, and epoxy. Examples of naturally occurring polymers are silk, wool, DNA, polysaccharide and proteins. Green and Natural Polymers Are on the Rise. As their name implies, natural polymers (or biopolymers) are polymers that occur naturally or are produced by living organisms (such as polysaccharide, silk, chitin, protein, DNA).
SESSION 06: 3D PRINTING POLYMERS
The powder will be chemical compound or many other alternative materials and a range of binders will be utilized based on the powder used. Fused filament fabrication (FFF) (or fused deposition modelling – FDM) was developed in the early 1990s as another 3D printing approach that like SLS uses preformed polymer as the building material. PLA is a biodegradable plastic made from renewables such as corn-starch. While several 3D-printer manufacturers are providing metal 3D-printing services, it’ll be some time before the economies of scale that helped bring down the price of plastic 3D printing affect the DMLS market.
SESSION 07: BIO-CATALYSIS IN POLYMER CHEMISTRY
Bio-catalysis refers to the use of natural substances that include enzymes from biological sources or whole cells to speed up chemical reactions. Enzymes have pivotal role in the catalysis of hundreds of reactions that include production of alcohols from fermentation and cheese by breakdown of milk proteins. Bio-catalysis have many advantages over chemo catalysis in the context of green chemistry, which include mild reaction conditions (physiological pH and temperature), the use of environmentally compatible catalysts (enzymes) and solvents (usually water), high chemical activity and sensible regio- and chemo-selectivities for multifunctional molecules.
SESSION 08: POLYMER SCIENCE AND APPLICATIONS
A polymer is a massive molecule, or macromolecule, composed of many repeated subunits. Due to their broad range of properties, each artificial and natural polymer plays essential and omnipresent roles in everyday life. The field of chemical compound science includes researchers in multiple disciplines including chemistry, physics, and engineering. Polymers are studied with in the fields of physics science and macromolecular science, and polymer science (which include polymer chemistry and polymer physics).
SESSION 09: OILS AND BIO-INORGANIC MATERIALS
Bioinorganic chemistry may be a field that examines the role of metals in biology. Many biological processes like respiration depend upon molecules that fall within the realm of inorganic chemistry. Bioinorganic chemistry is the behavioral study of metalloproteins as well as artificially introduced metals including non-essential, in medicine and pharmacology.Bioinorganic Materials and Nanotechnology session is especially to phenomena and processes together of inorganic materials, nanomaterials and biological systems.
SESSION 10: POLYMER ENGINEERING AND TECHNOLOGY
Polymer engineering is mostly associated with an engineering field that designs, analyses, and modifies polymer materials. Engineering polymers are materials with superior structure–property correlations. These properties enable the use of the engineering polymers in specific, high-end applications in automotive and aerospace industries. The recent developments of chemical compound have revolutionized the sphere of fabric science increasing the use of chemical compound primarily based substances from building materials to Packing materials, Fancy decoration articles, Electrical engineering, Communications, Automobile, Aircrafts, etc.
SESSION 11: NANO -POLYMERS AND NANOTECHNOLOGY
Polymer Nano-composites consist of a polymer or copolymer having Nano particles dispersed in the polymer matrix. Polymer nanotechnology group can develop enabling techniques for the patterning of practical surfaces. Polymer Nano science is that the study and application of Nano science to polymer-nanoparticle matrices, wherever nanoparticles are those with at least one dimension of less than 100 nm. The most common type of filler particles utilized by the tire industry had traditionally been Carbon black (Cb), produced from the incomplete combustion of coal tar and ethylene.
SESSION 12: POLYMER ELECTRONICS: OPTICS, FIBER AND LASERS
Polymers are increasingly being used in a wide variety of applications in electronics and photonics, most of which use polymers in their traditional role as engineering materials. For more than 50 years, we have been developing and manufacturing polymer optical components and complex optomechanical electronic systems for our customers using sophisticated injection molding process. Metal nanoparticles have been used since the medieval times to create beautiful colours in glass windows. The effect is a result of strong colour-dependent light absorption in metal nanostructures; through excitation of collective electron oscillations known as plasmons.They are associated with doped fiber amplifiers, which give light-weight amplification without lasing.Fiber nonlinearities, like stimulated Raman scattering or four-wave mixing can also provide gain and thus serve as gain media for a fiber optical device.
SESSION 13: POLYMERS IN PETROLEUM REFINERY
The chemical gas polymerization process of the UOP operates on olefin-containing gases. In both thermal and catalytic polymerization processes, the feedstock is usually pretreated to remove sulfur and nitrogen compounds. This method converts propylene and butylene to high-octane fuel or petrochemical polymers. Polymerization may be a method in which a substance of low molecular weight is transformed into one of the same composition but of higher molecular weight, maintaining the atomic arrangement present in the basic molecule.The stability of petroleum is dependent upon the molecular relationships of asphaltene and organic compound constituents and also the balance with the other constituents of petroleum. The asphaltene constituents are the highest molecular weight heaviest and most polar compounds in crude oil. During crude purification, the asphaltene compounds are non-distillable and remain in the residual fuels as the distillable fractions are removed.
SESSION 14: POLYMERS IN MEDICINE
Polymers play a crucial role in medical applications and biomaterials are already habitually used in clinical applications. However, several medically approved polymers are not yet optimized for their aspired application. Properties such as mechanical characteristics, plasticity and degradation behaviour need to be adapted to the designated application. For medical applications, the surface properties are of major importance. Polymers are also constantly gaining attention in trendy biomaterial analysis wherever polymeric materials should act as mechanically stable, degradable and custom-made scaffolds, drug carriers or hydrogel-based artificial biomimetic living thing matrix. In this space, major progresses can be achieved via 3D printing of hierarchical materials with tissue-like structures.
Polymer drug conjugates play a crucial role in the delivery of drugs. In the polymeric drug conjugates, the bioactive agent is combined covalently with chemical the substance to realize the efficient delivery of bioactive agents with in the required or specific period of time along with the enhancement of permeability and retention time. Among them, could be a biodegradable polymer having versatile nature due to its 2 chemical element atoms connected on each sides of phosphorus atom of its polymeric backbone, it can be easily replaced by nucleophilic substitution reaction. Plastic packaging for food and non-food applications is non-biodegradable, and also uses up valuable and scarce non-renewable resources like fossil fuel.
Futures of Bio-polymers demand the manufacturer for brand spanking new materials is overwhelming. Applications by the use of new materials should utilize the properties of those polymers, and also the products should be developed based on those properties. The main concerns for humans in the future can be energy & resources, food, health, mobility & infrastructure and communication. Synthetic polymers have since an extend time played a relatively important role in present-day medicinal observations. Polymers occupy a prominent role in this modern living. From the tooth brush, lunchboxes, toys, pens etc, a lot of products are being used every day. It is absolutely fascinating when we understand the polymers and its utmost functionalities. From the daily utilities to the most advanced areas of research, polymer is a fundamental component. Man synthesized artificial polymer mimicking the natural polymers, which is a group of molecules combined together.
SESSION 17: SMART MATERIALS APPLICATION IN AI
The latest research on Intelligent Systems, Robot, Automation, Smart Home, Smart Materials for Precision Sensors / Actuators, Display Materials and Imaging Products, Shape Memory Materials, 3D/4D Printing and Additive Manufacturing will be addressed in this session.
The latest Optical Communication and 4G/5 G Communications, Piezoelectrics, Ferroelectrics, Pyroelectrics, and Optoelectronic Materials research is being discussed in this session.
We will be addressing the latest research on Flexible and Stretchable Electronics, Integrated Circuit and Semiconductor, Electronic & Advanced
Packaging Materials and Engineering, Magnetic and Multiferroic Materials and Novel Superconductors in this session.
SESSION 20: SMART NANOMATERIALS
In this session, we are discussing the current research on NanoThin Film and Nanocoatings, Nanoparticles, Nanopowders and Nanocrystals, MEMS, NEMS, NanoDevices and Array Technologies, Nanotechnology and Microtech, Nanomedicine, MAX Phase Design and MXenes, Mart Power and Environmental Materials.
In this session, we are discussing the current research on Pharmaceutical Products Smart Biomaterials, Drug Delivery,Disease Diagnosis & Treatment, Biomimetic Materials, Biomedical Materials, and Tools.
In this session, we are discussing the current research on Materials and Surface Science Design, Modeling, Production, Processing, Synthesis, Analysis & Testing, Smart Materials Applications throughout Architecture and Civil Engineering, Smart Materials Applications in Automotive, Defense, Military & Aerospace Engineering.
Market Analysis
The global polymer industry is expected to grow with a CAGR of 3.9% over 2015-2020. The demand for polymer is driven by growth in end use markets, such as packaging, automotive, infrastructure, transport rails, and telecommunication mainly from emerging economies. Polymer is continuously substituting metals, glass, paper, and other traditional. The global Polymer Filler Market size exceeded USD 45 billion in 2015. Increasing demand for high strength and lightweight materials in the automotive and industrial applications is likely to propel the low-density Polymer Filler Market. Polymer fillers due to their improved impact strength are expected to replace costly plastic resins across various industrial products soon. Polymer fillers are likely to gain wider acceptance in various industrial products due to the increasing use of low-cost fillers in countries such as the U.S, India, Germany, Brazil, etc. Stringent guidelines and environmental regulations are expected to influence the global Polymer Filler Market.
The global polymer industry segmented by regions:
The global polymer industry segmented by types:
Companies Mentioned:
Universities Related to Analytical Chemistry:
Companies related to Chemistry: