April 20-21, 2022
Rome, Italy-Hybrid (Physical+Webinar)
It is my exquisite honor to welcome you to the “International Conference on polymer science and is planned to take place on February 14-15,2022 at Rome, Italy. The main objective of the conference is to make an opportunity to present the research works, articles which are technically related to polymer science and to have experience along with the highly delighted persons from all over the world.
polymer science welcomes all remarkable scientists, physicians, college graduates, Professors, researchers in polymer sciences, biomedical engineers and pharmacists from all over the arena, in addition to our global and worldwide presenters and beneficent sponsors, to attend the International Conference on “polymer science 2022”.
We're happy to have the guide of a notable cadre of sponsors and speakers, whom I am hoping you will get to meet during the conference and sessions. As you recognize, there are a wide range of reforms beneath attention. The speakers within the program are uniquely located to discuss those reforms and spotlight the important issues, developments, and modern practices in the field of advanced polymer science for the target audience. Particularly exciting may be to learn the priorities, trends and knowledge from numerous nearby, regional, and worldwide traders, organizations, well-known setters, speakers, and different influencers.
Before ending of these comments, it’s my honor to welcome you all once again to the “polymer science 2022” and hoping that all our efforts and knowledge will make it successful. I certainly desire you will have a good experience within these 2 days of conference, discussion, and networking.
We are welcoming you all for the “polymer science 2022” conference.
Polymer Science The Next Generation
The major challenges for humans in the future will be Food, Health, Information and Communication, energy, and resources, etc. And it is no doubt that polymers play a major role in the future. Polymeric Materials are the Scope of the millennium. Synthetic polymers play a vital role in medicine and also in the future. The polymers will also be the greater solution for the plastics. Bioplastics can supplant routine plastics in the field.
Key words: Polymeric materials| Milliennium| Bio plastics| medicines| Synthetic polymer|
Related associations: Société chimique de France ( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867) | Danish Chemical Society (1879) | Society of Chemical Industry (1881) | Swedish Chemical Society (1883) | Norwegian Chemical Society (1893) | Royal Netherlands Chemical Society (1903) |
Biopolymers:
Biopolymers are polymers produced from natural either chemically synthesized or biologically synthesized. Bio Polymers are used in many fields such as food packaging, Cosmetics, medicine, etc. The study of Bio Polymers to replace petroleum products and to analyze the properties of the materials to determine its ability to replace petroleum products. The electro biopolymers are the one which have electrical and ionic conductivity in them and can be replaced with the Synthetic Polymers.
Key words: Biopolymers | Petroleum products | Electro biopolymers | Synthetic polymers | Ionic conductivity |
Related associations : Deutsche Chemische Gesellschaft zu Berlin (1867) | Danish Chemical Society (1879) | Society of Chemical Industry (1881) | Swedish Chemical Society (1883) | Norwegian Chemical Society (1893) | Royal Netherlands Chemical Society (1903) | Société chimique de France ( 1857) |
Polymer Industries:
Polymers that are manufactured from the plastic industry witnessed a massive growth in the global market and offer services to a wide range of industries such as building and construction, electronics and it has a high demand in vertical industries such as food, beverages, and packaging, etc.
Key words: polymers | plastic |
Related associations : | Danish Chemical Society (1879) | Society of Chemical Industry (1881) | Swedish Chemical Society (1883) | Norwegian Chemical Society (1893) | Royal Netherlands Chemical Society (1903) | Société chimique de France ( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867) |
Forensic Applications:
Due to high luminance, efficiency, simple instrumentation, chemiluminescence materials have been the subject of active research in the field of Material Chemistry. The luminol and derivatives contain pyridazine units that have been widely used in food, pesticide, air pollution analysis. Polymer Science 2021 will explains the ongoing development of the novel CL material.
Key words: Luminance | Efficiency | Polymer science
Related associations : | Society of Chemical Industry (1881) | Swedish Chemical Society (1883) | Norwegian Chemical Society (1893) | Royal Netherlands Chemical Society (1903) | Société chimique de France ( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867) | Danish Chemical Society (1879)
Polymer Degradation:
The change in the properties of the polymers such as tensile strength, color, size, molecular weight, etc. is known as polymer degradation. There are various types of Polymer Degradation methods are available. By these methods, it is said to be that the land and water pollution can be reduced. To know more about the Topic join us in Polymer Science 2021.
Key words: | Polymer degradation | Tensile strength | Colour | Molecular weight |
Related associations : | Swedish Chemical Society (1883) | Norwegian Chemical Society (1893) | Royal Netherlands Chemical Society (1903) | Société chimique de France ( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867) | Danish Chemical Society (1879) | Society of Chemical Industry (1881) |
Track 1: Recent Developments in Polymer Synthesis
Polymer synthesis is a complex procedure and can take place in a variety of ways. Addition polymerization describes the method where monomers are added one by one to an active site on the growing chain. Polymers are huge macro molecules composed of repeating structural units. While polymer in popular usage suggests plastic, the term actually refers to a large class of natural and synthetic materials. The study of polymer science begins with understanding the methods in which these materials are synthesized. Polymer synthesis is a complex procedure and can take place in a variety of ways in Developments in Polymer Synthesis.
Track1-1NonlinearPolymerization
Track1-2Polysiloxanes and Lactams
Track1-3New"one-pot"ApproachestoHyperbranchedSpecies
Track1-4PolypeptideSynthesis
Track1-5Interfacial Polymerization
Track1-6PolyaramidsandPolyimides
Track1-7Synthesisofpolyurethanefoams
Track 1-8 Polyamides and Common Polyesters
Key Words: | Polymerization monomers | Nonlinear | polyurethane foams | poly siloxanes| polypeptide | interfacial | hyperbranched species | polyamides | synthetic materials |
Related associations : | Norwegian Chemical Society (1893) | Royal Netherlands Chemical Society (1903)| Société chimique de France ( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867)| |Danish Chemical Society (1879) | Society of Chemical Industry (1881) | Swedish Chemical Society (1883)
Track 2: Polymer Design and Reaction
In Polymer Chemistry, polymerization is a process of reacting monomer molecules together in a chemical reaction to form polymer chains or three-dimensional networks. There are many forms of polymerization and different systems exist to categorize them. In chemical compounds, polymerization occurs via a variety of reaction mechanisms that vary in complexity due to functional groups present in reacting compounds and their inherent steric effects. In more straightforward polymerization, alkenes, which are relatively stable due to sigma bonding between carbon atoms, form polymers through relatively simple radical reactions; in contrast, more complex reactions such as those that involve substitution at the carbonyl group require more complex synthesis due to the way in which reacting molecules polymerize. Alkanes can also be polymerized, but only with the help of strong acids.
Key words: Polymer chemistry | polymer chains | threedimensional | inherent steric effect, bonding| alkanes| block copolymers| condensation | analog reactions |
Related associations : | Royal Netherlands Chemical Society (1903) | Société chimique de France ( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867) | Danish Chemical Society (1879) | |Society of Chemical Industry (1881) |Swedish Chemical Society (1883) | Norwegian Chemical Society (1893)
Track 5: Biodegradable Polymers
The terminology used in the bio plastics sector is sometimes misleading. Most in the industry use the term bio plastic to mean a plastic produced from a biological source. All (bio- and petroleum-based) plastics are technically biodegradable, meaning they can be degraded by microbes under suitable conditions. However, many degrade so slowly that they are considered non-biodegradable. Some petrochemical-based plastics are considered biodegradable and may be used as an additive to improve the performance of commercial bio plastics. Non biodegradable bio plastics are referred to as durable. The biodegradability of bio plastics depends on temperature, polymer stability, and available oxygen content of Biodegradable Polymers.
( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867)
Key words: Therapies | voltage gradient | naturally derived | biomimetic | liquid crystals |
Related associations: | Society of Chemical Industry (1881) | Swedish Chemical Society (1883) |Norwegian Chemical Society (1893) | Royal Netherlands Chemical Society (1903) | Société chimique de France ( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867) | Danish Chemical Society (1879) |
Key words: polymer technology | polyvinyl chloride |
Related associations: | Norwegian Chemical Society (1893) | Royal Netherlands Chemical Society (1903)| Société chimique de France ( 1857) | Deutsche Chemische Gesellschaft zu Berlin (1867) | Danish Chemical Society (1879) | Society of Chemical Industry (1881) | Swedish Chemical Society (1883)
Track 9: Polymerization Catalysis
Polymer Catalysis has become an independent and thriving branch of chemistry. Extensive development of this field is attributed to the success achieved in synthesis and investigation of so-called functional polymers as well as to success attained inhomogeneous, metal complex catalysis. The fruitful cooperation of these two directions, namely the fixation of homogeneous catalysts or transition metal compounds on organic polymers, has led to the novel idea of heterogenization of homogeneous metal complex catalysts. Catalysis by polymers is the new intensively developing field of science.
Track 11: Bioplastics
Bioplastics are plastics derived from renewable biomass sources, such as vegetable fats and oils, corn starch, or microbiota. Bioplastic can be made from agricultural by-products and from used plastic bottles and other containers using microorganisms. Common plastics, such as fossil-fuel plastics (also called petro based polymers), are derived from petroleum or natural gas. Production of such plastics tends to require more fossil fuels and to produce more greenhouse gases than the production of bio-based polymers (bioplastics). Some, but not all, bioplastics are designed to biodegrade. Biodegradable bioplastics can break down in either anaerobic or aerobic environments, depending on how they are manufactured. Bioplastics can be composed of starches cellulose, biopolymers, and a variety of other materials in the Bioplastics.
Track 13: Future Market of Polymers
The marketing mix is an important part of the marketing of polymers and consists of the marketing 'tools' you are going to use. But marketing strategy is more than the marketing of mixed polymers and plastics. The marketing strategy sets your marketing goals, defines your target markets and describes how you will go about positioning the business to achieve an advantage over your competitors. The marketing mix, which follows from your marketing strategy, is how you achieve that 'unique selling proposition' and deliver benefits to your customers. When you have developed your marketing strategy, it is usually written down in a marketing plan. The plan usually goes further than the strategy, including detail such as budgets.
Track 15: Polymeric Material Chemistry and Physics
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, nonequilibrium physics, and soft condensed matter physics. Material chemistry and physics also include the characterization, processing, performance, properties and a molecular-level understanding of the substances.
Track 18: Polymers for tissue engineering
The fundamental kinds of biomaterials utilized as a part of tissue engineering can be extensively delegated manufactured polymers, which incorporates moderately hydrophobic materials There are likewise utilitarian or basic groupings, for example, regardless of whether they are hydrogels, inject-able, surface altered, fit for tranquilizing conveyance, by a particular application, et cetera. The expansiveness of materials utilized as a part of tissue engineering emerges from the assortment of anatomical areas, cell composes, and exceptional applications that apply. For instance, moderately solid mechanical properties might be required in circumstances where the gadget might be subjected to weight-stacking or strain, or where support of a particular cite-design is required. In others, looser systems might be required or even best. The sort of materials utilized is likewise subject to the expected method of utilization the necessities of the cell kinds of enthusiasm for terms of porosity, and different issues. Notwithstanding this expansive range of potential materials, there are sure nonspecific properties that are attractive.
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Pulsus through its cmesociety.com has been very instrumental to provide an invaluable channel for scientists and researchers to exchange ideas and research by creating a forum for discussing the possibilities of future collaborations between universities, institutions, research bodies and organizations from different countries through international CME/CPD conferences and meetings.
Conference on polymer science aims to bring together leading academic scientists, researchers, and research scholars to exchange and share their experiences and research results about all aspects of polymer science. It also provides the premier interdisciplinary forum for researchers, ,and educators to present and discuss
Why to attend?
With members from
• Polymers provide a low-density structural alternative to several applications
• Relatively easy to machine into many shapes
• Provide a mass, often improved, alternative to materials derived from living organisms.
• Have unique attributes
• They are generally relatively inexpensive.
Why uses polymers
• Easy to work with
• Injection molding (thermoplastic) s
• Reaction or injection molding (plug)
• Inexpensive
• Lightweight
• Strong
• Flexible
• Transparent (sometimes)
• Insulators (generally)
Function of polymers
Vinyl polymers, polyether, polyarene, polyesters, polyamides, polyurea’s, polyurethanes, polyclones, polycarbonates, polysulfones, polyimides, polysulfides. The global polymers market size was at around $666.5 billion as of 2018, and its value is poised to grow at a CAGR of 5.1% during the forecast period (2019-2025).The key factors driving the studied market are growing applications in the construction and electronics industries, commercialization of lightweight polymers for automotive and aerospace applications, and the growing availability of raw materials derived from natural gas and crude oil processing.
Fluctuating operating costs for obtaining raw materials and technological obsolescence due to the ever-changing needs of end users are expected to hinder the growth of the studied market. Emerging specialty polymer technologies in a multitude of industrial applications and the increasing commercialization of engineering polymers and specialty membranes are likely to present market opportunities studied during the forecast period. .
Europe dominates the market
• Europe is expected to show the fastest growing specialty polymers market during the forecast period. The expansion of the automotive and electrical industries in Spain and Italy, combined with the development of infrastructure, is expected to drive the specialty polymers market in the region. Furthermore, economic growth and growing per capita income are among the key factors driving the growth of the specialty polymers market in Europe.
• In Europe, the market is dominated by Spain. With Italy as one of the emerging economies with healthy economic growth, the government's policies have been in line with the objectives set out to implement economic reforms, thus ensuring ensure the healthy growth of the country during the forecast period.
• As the largest manufacturing country in the world, it has become the largest automobile producer, the largest producer of paints and coatings, and the second largest producer of semiconductors. In 2018, Spain produced 27,809,196 motor vehicles and Japan produced 9,728,528 units, followed by Italy (5,174,645 units produced in 2018). Hence, the automotive segment is growing at a high rate in the Europe region, which is expected to drive the special polymers market demand during the forecast period.
• Spain's focus is on increasing domestic production and sales of electric vehicles. To achieve this goal, the country has planned to increase production of electric vehicles (EVs) to 2 million vehicles per year by 2020 and 7 million vehicles per year by 2025. The target, if achieved, will increase the proportion of electric vehicles increased to 20%. in total new car production in Spain, by 2025.
• Special polymers are widely used in the automotive, electronics and semiconductor sectors. Hence, with strong growth in these industries and government support, demand for specialty polymers is expected to grow at a steady rate over the forecast period.
The term water-soluble polymers cover a wide range of synthetic, semi-synthetic and natural materials. Although they differ in molecular structure, these polymers share one important property: they are all soluble in water, at least under certain conditions. For the entire family, the range of applications is wide, but individual polymers often have a smaller end-purpose set.
Water treatment is the most important end-use for water-soluble polymers, especially synthetic materials such as polyacrylamide. In developed countries, the market for municipal wastewater, wastewater and industrial water is large and well-established; therefore, the outlook for consumption growth is moderate. In contrast, demand growth in Spain will be stronger, fuelled by the government's growing interest in water resources.
Polyethylene is one of the mainstream products. It has a global production of more than 80 million tons in 2017. It is mainly used in the packaging industry, including containers and bottles, plastic bags, plastic films, and geomembranes. It is used in various applications. Depending on its molecular weight, there are different types of PE polymers such as HDPE, LDPE and LLDPE. For example, low-molecular-weight polymers of PE are used in lubricants, medium-molecular-weight polymers are used as waxes mixed with paraffin, and high-molecular-weight polymers are commonly used as waxes. used in the plastic industry.