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polymer materials 2021

About Conference

“World Congress on Polymers and Functional Materials” during September 28-29, 2021 in Auckland, New Zealand which includes prompts keynote presentations, Oral talks, Poster presentations and Exhibitions.

While much research and product development in industry is product oriented, it requires scientists with a grasp of the foundations of chemistry, creativity, the ability to work together, and enjoy seeing the practical applications of their work. Polymer Materials 2021 covers all the aspects of related field researchers, The forum of Scientists, and students from all corners of the globe, come together to discuss about polymer science and its advances.

Each session of the meeting will be included with expert lectures, poster and discussions, join us to design sustainable development processes, innovations by which and how these strategies drive new policies, advances the business and sustainability in drug production for further health care protection of lives. We are glad to invite you on behalf of organizing committee to join us, where you are the decision maker for future.

Why to attend???

World Congress on Polymers and Functional Materials 2021 which is going to be the biggest conference dedicated to polymer chemistry focusing on "Recent Advancements and developments in Polymers" and provides a premier technical forum for reporting and learning about the latest research and development, along with discussing new applications and technologies. Events include hot topics presentations from all over the world and professional networking with industries, leading working groups and panels.

Meet Your Objective Business sector with individuals from and around the globe concentrated on finding out about Polymer chemistry, this is the best chance to achieve the biggest collection of members from everywhere throughout the World. Conduct shows, disperse data, meet with current, make a sprinkle with another product offering, and get name acknowledgment at this occasion. Widely acclaimed speakers, the latest methods, strategies, and the most up to date overhauls in Polymer science and Engineering are signs of this meeting.

Target Audience:

Eminent Scientists

Research Professors in the field of polymer chemistry

Junior Senior research fellows

Students

Directors of polymer research companies

Chemical Engineers

Members of different physics and Chemistry associations

Chemical engineering Research Professors

Junior/Senior research fellows of biomaterials and bio products

CEO's of biopolymers companies

Members of different physics associations of Biopolymers and bio plastics

Biopolymers doctorates

Sessions and Tracks

Sessions & Tracks

1. Polymer Marketing

Polymer demand in Europe has long been renowned amongst the world leaders. it's presently facing superficially restricting maturity within the West and therefore the question is currently, of a way to add price throughout the availability chain. Central Europe is seeing increasing investment in industrialized and plastic process, with several countries cashing in on free access to the only market not to mention an occasional production prices. Russia and therefore the former state Democracies still have lots of unsuccessful potential, deteriorated by poor republics dealings and political economy. The smaller states within the region square measure experiencing a fast growth of technological capability that offers nice opportunities, but at a similar time, threatens long established markets within the west the compound market is massive and numerous and despite increasing process, opportunities unit gift in today’s climate while not prime quality information it's troublesome to arrange future investments and promoting ways. AMI’s latest report provides careful applied math analysis of wherever growth opportunities lie and therefore the nature of the trade. This report can assist any company wish to raised perceive the ecu industry

AMI's 2015 European industry Report, European compound markets square measure forecast to grow by one.3% this year, building on a recovery of but I Chronicles for 2014. However, even this modest gain is underneath risk from the region's tight provide for several materials and chop-chop economic process. As a result the ecu industry in 2015 finds itself in another amount of upheaval and alter because it appearance to tug out of the unproductivity caused initial by the nice Decline in 2008-2009 then by the Eurozone crisis 2012-2013. within the 2 years since AMI printed its last review, in 2013, demand has barely shifted from simply over thirty-six million tones and therefore the volume of polymers consumed in 2014 was still some 100 percent below that utilized in 2007 before the nice Recession hit.

2. Polymers for Drug Delivery

Polymers have contend Associate in Nursing integral role among the advancement of drug delivery technology by providing controlled unhitch of therapeutic agents in constant doses over long periods, cyclic quantity, and tunable unhitch of every hydrophilic and hydrophobic drugs. From early beginnings mistreatment ready-made materials, the sphere has huge massively, driven partly by the innovations of chemical engineers. Modern advances in drug delivery are presently predicated upon the rational kind of polymers tailored for specific consignment and engineered to exert distinct biological functions. Throughout this review, we've got a bent to spotlight the essential drug delivery systems and their mathematical foundations and discuss the physiological barriers to drug delivery. we've got a bent to review the origins and applications of stimuli-responsive compound systems and compound medicine like polymer-protein and polymer-drug conjugates the foremost recent developments in polymers capable of molecular recognition or leading object delivery unit of measurement surveyed perhaps areas of research advancing the frontiers of drug delivery.

3. Biopolymers

“Polymeric biomolecules” or the Biopolymers are polymers fabricated by living organisms. Polynucleotides, Nucleotides and Polypeptides are the three main classes of polymers those are called long polymers.it also have short polymer of amino acids and polysaccharides which are frequently linear bonded polymeric carbohydrate structure for example examples: rubber, suborn, melanin and lignin.

Structure of the biopolymer has a well- defined. The difference between biopolymer and synthetic polymer can be found in their structure. Compare to biopolymer synthetic polymer has much simplest structure. This fact shows to a molecular mass distribution that is missing in biopolymers. All biopolymers are alike that they all contain the similar sequences and numbers of monomers and thus all have the same mass.

Polymer hybrid assemblies
3D printing of materials in Biopolymers
Surface and Interfaces of Biopolymers

4. Nanomaterial and Nanotechnology

In Nanomaterial and Nanotechnology the term ‘Nano’ is derived from the Greek ‘Nanos‘ which is known as extremely small particle. Basically nanomaterial is material with dimensions on the Nano-scale. Structure at Nano-scale has unique optical, electronic, or mechanical properties. Actually, nanomaterial’s cover huge areas of materials of materials, many of which we would not normally consider to be particularly revolutionary. Because nature is full of nanomaterial’s and Nanostructure. Nanotechnology is the engineering of operative systems at the molecular scale. This covers both present work and concepts that are more advanced. In this real world today the nanotechnology has ability to build products using techniques and equipment’s to produce completely high performance products. The idea that seeded nanotechnology were first discussed in 1959 by renowned physicist Richard Feynman in his talk there’s Plenty of Room at the Bottom in which it explained about the possibility of synthesis via direct manipulation of atoms.

Tissue engineering
Polymer Nano composites matrices
Poly condensation polymerization
Nano electronics & photonics
Polymer films
Bio-hybrid polymer Nano fiber
Block copolymer Nano composites
Higher-order polymer structures

5. Polymer Rheology

The study of flow of matter is known as Rheology basically in a liquid state, but also responds for "soft solids" or solids like plastic flow rather than deforming elastically in response to applied force. It is a department of physics which deals with the deformation and flow of materials, both solids and liquids. Rheology generally accounts for the behavior of non-Newtonian fluids, by distinguish the minimum number of functions that are needed to relate stresses with rate of change of strain or strain rates. Rheometry is experimental characterization of a material's rheological behavior .In execution, rheology is principally concerned with prolong continuum mechanics to characterize flow of materials, that indicates a combination of elastic, viscous and plastic behavior by properly combining elasticity and (Newtonian) fluid mechanics. Rheology has many application in polymer science and engineering, pharmaceutics, biology and physiology.

6. Polymer Degradation and Stabilization

Polymer Degradation and Stability deals with the degradation reactions and their management that area unit a heavy preoccupation of practitioners of the various and various aspects of recent chemical compound technology. Deteriorative reactions occur throughout process, once polymers are subjected to heat, oxygen and mechanical stress, and through the helpful lifetime of the materials once oxygen and daylight are the foremost vital derivative agencies. In additional specialized applications, degradation is also iatrogenic by high energy radiation, ozone, atmospherically pollutants, mechanical stress, biological action, chemical reaction and lots of alternative influences. The mechanisms of those reactions and stabilization processes should be understood if the technology and application of polymers are to still advance.

7. Biodegradable polymers

Biodegradable polymers are outlined as Polymers comprised of monomers joined to at least one another through functional groups and are de-escalated into biologically acceptable molecules that are metabolized and off from the body via traditional metabolic pathways. The event of biodegradable polymer composites promotes the use of environmentally friendly materials. Most within the business use the term bio plastic to mean a plastic created from a biological supply. All petroleum-based plastics were technically biodegradable. Biodegradable Polymers also can use to regulate the drug unleash rate from the formulations. Current and future developments in biodegradable polymers focus to scaling-up of upgrading and production of product properties leading to reduction in costs and augmented availableness.

8. Polymers for energy applications

Conductive polymers consolidate the attractive properties related with traditional polymers and special electronic properties of metals or semiconductors. As of late, nanostructured conductive polymers have stimulated significant research enthusiasm because of their special properties over their macro-scale counterparts, for example, large surface area and short distances for charge/mass transport, making them potential candidates for expansive applications in energy storage and conversion, actuators, sensors and biomedical devices. Various synthesis techniques have been created to produce conductive polymer nanostructures and high performance devices in view of these nanostructured conductive polymers. This provides us with various applications of nanostructured conductive polymers such as electrode material for electrochemical capacitors and lithium-ion batteries and new perspective of practical materials for cutting edge high-energy batteries. Recently fuel cell systems with polymer-based electrolytes are of special interest for certain applications due to their relatively simple and compact design and high power densities. On the fundamental level, they are further classified according to the nature of ionic-conducting species in the polymer-based electrolyte, i.e., acidic (proton conducting) or alkaline (hydroxide ion conducting) membranes. Solar cells are one of the most reliable renewable sources of energy and but it is not the most efficient. Therefore, there is constant progress in improving the solar cells to provide greater efficiency. For this development different materials have been tested, among them are polymers. The polymer solar cells have a wide range of application including flexible solar modules and semi-transparent solar cells in windows, to building applications and even photon recycling in liquid-crystal displays.

9. Polymer +3D Printing

From a synthetic bone fabricated from acrylic to custom confections created from chocolate, the globe of 3D printing keeps obtaining additional superb. Today, 3D printers will enable individuals to form just about something, employing a form of materials, from metal and ceramic to sugar and polystyrene. Of course, plastic is that the substance that 1st created 3D printing of any kind doable, and plastic remains one in every of the foremost common and versatile styles of materials employed in 3D printing. A commenter on a recent compound Solutions journal asked for data regarding the foremost common styles of plastics employed in 3D printing. Here’s a touch bit regarding the 3 most-frequently used plastics that have helped spur the superb evolution of 3D printing:

A terpolymer invented by polymerizing polyvinyl resin and vinyl cyanide with poly butadiene, ABS is another plastic unremarkably employed in 3D printing. Beginners particularly favor it for its simple use in its filament kind, and since it’s sturdy, strong, heat-resistant, efficient and versatile. , PLA is created from renewable, organic resources like corn starch or sugarcane. It’s unremarkably wont to create food packaging and perishable medical devices and implants. PLA is nice for 3D printing as a result of it’s straightforward to figure with, environmentally friendly, accessible in a very sort of colors, and may be used as either a organic compound or filament.

Of course, the vary of materials which will be employed in 3D printing continues to expand and evolve beside the method and its applications. Still, one in every of the foremost superb developments in producing traces its beginnings to the initial “space-age” material — plastic. Which strikes America as terribly fitting.

10. Commercial application of biopolymers and Polymer Applications

A large variety of biopolymers, such as polysaccharides, polyesters, and polyamides, are naturally synthesized by microorganisms. These biopolymers range from viscous solutions to plastics and their physical properties which are dependent on the composition and molecular weight of the polymer. Genetic engineering of microorganisms has provided an enormous potential for the biotechnological production of biopolymers with desired properties suitable for medical application such as tissue engineering, material science, drug delivery and bio plastics. There are several benefits in commercializing biopolymers mostly for sustainable development, renewability and eco-friendly aspects. Bio plastics can be manufactured mainly with three different methods, one is modifying naturally occurring polymers such as starch, cellulose. Second, is by polymerizing bio-based monomers that are produced by fermentation and the last one, as mentioned earlier, by genetically modified microbes and plants. There are several technologies and processes designed for biopolymer production that include extrusion, film blowing, thermoforming, fermentation, injection molding, etc.

Polymers might sound sort of a terribly business specific issue, and to a point they're, however they're truly a reasonably massive a part of a great deal of industries you'll so acknowledge. Compound testing and practice for plastic has applications in such industries as part, automotive, physical science, packaging and medical devices. Polymers are implausibly numerous parts that represent such fields of engineering from aeronautics through medicine applications, drug delivery system, biosensor devices, tissue engineering, cosmetics etc. the applying of polymers and their resultant composites continues to be advancing and increasing quickly because of their ease concerning producing. Once considering a compound application, you may need to grasp however the fabric behaves over time therefore you'll be able to assess its real price. It’s necessary to grasp that chemical compound materials might include: raw materials, compound compounds, foams, structural adhesives and composites, fillers, fibers, films, membranes, emulsions, coatings, rubbers, protection materials, adhesive resins, solvents, inks and pigments.

11. Polymer Chemistry

Polymer chemists study large, complex molecules (polymers) that are built up from many smaller (sometimes repeating) units. They study how the smaller building blocks (monomers) combine, and create useful materials with specific characteristics by manipulating the molecular structure of the monomers/polymers used, the composition of the monomer/polymer combinations, and applying chemical and processing techniques that can, to a large extent, affect the properties of the final product. Polymer chemists are unique within the chemistry community because their understanding of the relationship between structure and property spans from the molecular scale to the macroscopic scale.

Polymer chemical professionals create, study, and manipulate the characteristics of polymers to create materials with specific chemical, biological, and physical properties. Polymers permeate every aspect of daily life, and it is difficult to imagine society without synthetic and natural polymers. Polymer products can be lightweight, hard, strong, and flexible, and may have special thermal, electrical, or optical characteristics. Because of their low cost, high specificity, and adaptability, polymers have a very wide range of applications.

They are used in the construction, furniture, electronics, communication, packaging, energy, health care, transportation, and sports & leisure industries, in everything from tractors to detergents to fabrics to aircraft. A polymer can be an end product in itself, or it can be an ingredient that changes the properties of another product.

The majority of polymer chemists work in industry, and focus on the end-use application of products, with an emphasis on applied research and preparation. Industrial polymer chemists need to adopt a business outlook and understand the commercial applications of the polymers they are developing and the needs of the market they are serving. They often find themselves working with the sales and marketing divisions of their companies to develop products that meet specific customer’s needs.

Biopolymer
Branched polymer
Copolymer
Macromolecular engineering

Market Analysis

Polymer chemistry is a multidisciplinary science that deals with the chemical synthesis and chemical properties of polymers which were considered as macromolecules. Furthermore, polymer chemistry is quite a broad field and has expanded to include overlapping with bio polymeric materials and materials chemistry. Polymers & plastics are some of the most important and most widely used chemical products in industry and consumer markets, they are used for manufacturing consumer products, such as coatings, lubricants, consumer goods, aerospace, building materials etc.

Trends, opportunities and forecast in the Global Market Analysis of Polymers are as follows:

Our analysts forecast the Global Specialty Chemicals Market to grow at a CAGR of 5.47% during the period 2018-2022.

Our analysts forecast the Global specialty polymers market to grow at a CAGR of 6.93% during the period 2018-2022.

The global super absorbent polymers market size was valued at USD 7.85 billion in 2016 and is expected to register an estimated CAGR of 5.8% from 2018 to 2022.

The global flexible plastic packaging market size was estimated at USD 131.24 billion in 2017 and our analysts forecast it to grow at a CAGR of 6.7% during the period 2018-2022

The global polymer foam market size was estimated at USD 113.9 billion in 2015 and is projected to expand at a CAGR of 6.6% from 2016 to 2024

The global styrenic block copolymers (SBCs) market size was valued at USD 6.26 billion in 2016 and is expected to grow at a CAGR of 6.3% over the forecast period

The global market for biodegradable plastics is projected to grow at a robust CAGR of 9.90% over the forecast period. The market value is expected to reach US$17.66 bn by the end of 2023

The global synthetic fibers market size was valued at USD 51,213.0 million in 2016 and is anticipated to register CAGR of 5.3% from 2017 to 2025.

The global polymer industry is expected to grow with a CAGR of 3.9% over 2015-2020. The demand for polymers is driven by the growth in end-user market, increasing plastic consumption, and increasing demand for essential light weight and significant low cost materials, as compared to its alternative. The application segment in the global polymer market includes industrial sectors, such as horticulture, consumer goods, packaging, building & construction, medical, packaging, automotive, transportation, food industry, and electronics and communication.Global Polymer Industry 2015-2020: Trend, Profit, and Forecast Analysis

The study also includes forecast of global polymer industry through 2020 segmented by regions and product types. The study also includes the global polymer industry segmented by applications for the –the year 2014.

To Collaborate Scientific Professionals around the World

Conference Date September 28-29, 2021

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Useful Links

Past Conference Report

Polymer Materials 2020 Conference

Supported By

Journal of Molecular and Cellular Biochemistry Journal of Biochemistry and Cell Biology Biopolymers Research

All accepted abstracts will be published in respective Conference Series International Journals.

Abstracts will be provided with Digital Object Identifier by

Polymer Materials

September 28-29, 2021 Auckland, Newzealand

Recent Advancements and Developments in Polymers

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