Sessions and Tracks
Track 1: Polymer Chemistry
Polymer scientific experts' examination huge, complex atoms (polymer) that are upgrade from numerous more modest (sometimes repeating) units. They concentrate how the more modest structure blocks (monomers) fuse, and make helpful materials with explicit attributes by controlling the sub-atomic construction of the monomers/polymers utilized, the synthesis of the monomer/polymer solidification, and applying substance and preparing procedures that can, generally, influence the properties of the end result. Polymer scientific experts are diverse inside the science local area in light of the fact that their comprehension of the connection among construction and property ranges from the sub-atomic scale to the perceptible scale. Polymer Chemistry is combining many specialized fields of expertise. It deals not only with the chemical synthesis, Polymer Structures and chemical properties of polymers which were esteemed by Hermann Staudinger as macromolecules but also covers other aspects of Novel artificial and chemical action ways, Reactions and chemistry of polymers, properties and characterization of polymers, Synthesis and application of polymer bio conjugation and also Polymer Nano composites and architectures. According to IUPAC recommendations, macromolecules are thought of relevant to the individual molecular chains and are the domain of chemistry. Industrial chemical compound chemistry has specific attention on the end-use application of product, with a smaller stress on applied analysis and preparation. Polymerization mechanisms and kinetics
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Novel synthetic and polymerization methods
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Hydrogen bonding and the phase behavior of polymer blends
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Supramolecular polymers
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Reactions and chemistry of polymers
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Reactions and chemistry of polymers
Track 2: Polymer Synthesis
Polymer researchers have been made an alternate cultivating system research in the advancement of biodegradable polymers, which could discover colossal applications in the space of clinical science. Today, extraordinary biopolymers have been arranged and used in various biomedical applications. In spite of the obvious multiplication of biopolymers in clinical science, the science and innovation of biopolymers is as yet in its beginning phases of advancement. Huge window exists and will stay to exist for the infiltration of biopolymers in each aspect of clinical science through escalated innovative work. Accordingly, this part tends to different polymerization strategies and methods utilized for the arrangement of biopolymers. The accentuation is on the properties of biopolymers, engineered conventions, and their biomedical applications. To make the helpful biomedical gadgets from the polymers to fulfil the needs of clinical science, different handling procedures utilized for the improvement of gadgets have been examined.
Track 3: Polymer Engineering
Polymer Engineering associate engineering field that styles, analyses, or modifies chemical compound materials. A polymer is a large molecule or a macro molecule which essentially is a combination of many sub units. The term polymer in Greek means ‘many parts’.
Polymers are all created by the bonds. Materials of Engineering refers to choosing the proper materials for the application in which process of polymerization wherein their constituent elements referred to as monomers, square measure reacted together to form polymer chair like 3 -dimensional networks forming the polymer the built part is being used. This selection process includes choosing the material, taking note to its specific sort or grade based on the required properties
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Design of materials
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Plastic material
Track 4: Polymeric Materials
Polymeric materials are used from prehistoric times. Polymers are abundant in nature, found in all living systems, and materials such as wood, paper, leather, natural fibers have found extensive use. While natural polymers retain their intrinsic importance, today synthetic materials are mostly used. The first semisynthetic polymers, formed by chemical modification of natural materials, were made in the second half of the nineteenth century. Absolutely synthetic polymers were developed in the twentieth century, most in the period 1950–1970s driven by industry growth. These are the so-called plastics of recent society. The feedstock for polymerization processes is petrochemical, and environmental issues have led to more recent developments of polymers from renewable resources.
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Polymers
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Rubbers
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Toughening
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Structures
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Interface
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Interphase
Track 5: 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 6: Polymer Nanotechnology
Nanotechnology is among the most recent research regions and it is characterized as building machines at the sub-atomic scale and includes the control of materials on a nuclear (around two-tenths of a nanometer) scale. It is the science and innovation of little things (fewer than 100 nm in size).This clearly incorporates polymer nanotechnology which incorporates microelectronics, polymer-based biomaterials, Nano drug, Nano emulsion particles; polymer bound impetuses, electro spun nano creation and so on. A polymer or copolymer material containing scattered nanoparticles is Nano polymer .The progress from smaller scale to nano-particles prompt change in its physical and in addition compound properties. Nano composites have turned into an unmistakable region of momentum innovative work. Polymer Nano composites (PNC) is a superior materials which comprise of a polymer or copolymer having nanoparticles or nano fillers scattered in the polymer network and devours 90% of generation of plastics. These might be of various shape (e.g., platelets, filaments, spheroids), however no less than one measurement must be in the scope of 1– 50 nm. It is considered as the materials of the 21st century because of its surprising property blends and extraordinary outline conceivable outcomes.
Track 7: Applications of Bio-Polymers
Biopolymers are available as coatings for paper rather than the more common petrochemical coatings. Bioplastics are used for disposable items, such as packaging, crockery, cutlery, pots, bowls, and straws. They are also often used for bags, trays, fruit and vegetable containers and blister foils, egg cartons, meat packaging, vegetables, and bottling for soft drinks and dairy products. These plastics are also used in non-disposable applications including mobile phone casings, carpet fibers, insulation car interiors, fuel lines, and plastic piping. New electroactive bioplastics are being developed that can be used to carry electric current. In these areas, the goal is not biodegradability, but to create items from sustainable resources. Medical implants made of PLA (polylactic acid), which dissolve in the body, can save patients a second operation. Compostable mulch films can also be produced from starch polymers and used in agriculture. These films do not have to be collected after use on farm fields.
Track 8: Polymer Physics
Polymer physics deals with the physical structure and also the properties of polymers, as well as the reaction kinetics of polymerization of monomers and degradation of polymers. Polymers are giant molecules and therefore are terribly sophisticated for resolution employing a settled methodology. In the state of liquid, polymer is strongly depends on the temperature. The thermal fluctuation affects the shape of a polymer when there is an external temperature is given to a liquid state of polymer. There are many applications of polymer physics with in the space of optoelectronics, coating, medicine, food and so on. The polymers can be made in a chain form. There are two types of polymer chain.
• Ideal chain model
• Real chain model
Track 9: Polymer Rheology
Rheology laboratory testing of polymers to determine the rheological (flow) properties of materials, gels and pastes, to optimize process and properties. Polymer physics testing is that the study of however the strain during a material or force applied is said to deformation and flow of the fabric.
Understanding the rheological properties of polymers through laboratory testing will help to optimize products and process conditions, thereby saving prices and minimizing potential waste. Our compound science specialists perform rheologic property testing on a good vary of polymers like polyolefin, liquids, adhesives, gels and pastes employing a big selection of temperatures and deformation rates (both shear and extensional). Rheology tests unit performed whereas the compound is inside the soften half or whereas the compound has been dissolved during a solvent for intrinsic consistency and relative consistency.
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Rheometer
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Viscometer
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Shear-thinning
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Generalized Newtonian fluids
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Limiting low shear viscosity
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Normal stress differences
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Analogy between continuous and oscillatory shear
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Time–temperature–pressure superposition
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Liquid failure
Track 10: Polymer3D 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.
Track 11: 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.
Track 12: Polymer Synthesis and Polymerization
Polymers synthesis determines the molecular structure and it will help us to avoid side reactions and achieve a worthy product. Polymerization polymers can be of many types. First one is the Chain growth polymerization and second is Step growth polymerization. In chain growth, polymerization is activated by the activation of neighboring monomers of a monomer. High molecular weight polymers are obtained quickly with a rapid process of chain growth polymerization. On the other hand, in step growth polymerization, bi functional monomers are combined in a systematic approach to build covalent bonds. In this process molecular weight increases slowly and in step wise.
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Low-density polyethylene (LDPE)
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High-density polyethylene (HDPE)
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Polypropylene (PP)
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Polyvinyl chloride (PVC)
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Polystyrene (PS)
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Thermoplastic polyurethanes (TPU)
Track 13: Polymer Degradation and Stabilization
Polymers synthesis determines the molecular structure and it will help us to avoid side reactions and achieve a worthy product. Polymerization polymers can be of many types. First one is the Chain growth polymerization and second is Step growth polymerization. In chain growth, polymerization is activated by the activation of neighboring monomers of a monomer. High molecular weight polymers are obtained quickly with a rapid process of chain growth polymerization. On the other hand, in step growth polymerization, bi functional monomers are combined in a systematic approach to build covalent bonds. In this process molecular weight increases slowly and in step wise.
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Photodegradable plastics
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Combustion studies
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Polymer photochemistry
Track 14: Polymer Science and Applications
A polymer is a massive molecule, or macromolecule, composed of many repeated subunits. Due to their broad vary of properties, every artificial and natural chemical compound plays essential and ubiquitous roles in daily 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).
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Electronics
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Optics
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Biomedical Applications-Regenerative Medicine, Drug Delivery, Bone Implants
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Polymers at surfaces and interfaces
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Energy conversion and storage
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Packaging
Track 15: Biopolymers & Biomaterials
Advanced polymeric Biomaterials continue to serve as a cornerstone of new medical technologies and therapies. The vast majority of these materials, both natural and synthetic, interact with biological matter without direct electronic communication. However, biological systems have evolved to synthesize and employ naturally-derived materials for the generation and modulation of electrical potentials, voltage gradients, and ion flows. Bioelectric phenomena can be interpreted as potent signaling cues for intra and inter-cellular communication. These cues can serve as a gateway to link synthetic devices with biological systems.
Track 16: Stereo chemistry of Polymers
When a polymer has stereo chemical isomerism within the chain, its properties often depend on the stereo chemical structure. Thus the analysis of the Stereo-Chemistry of polymers is important and NMR spectroscopy has been the most valuable tool for this purpose. It is a general rule that for a polymer to crystallize, it must have highly regular polymer chains. Highly irregular polymers are almost inevitably amorphous. Polymer chains can have isomeric forms that decrease the regularity of the chains.
Track 17: Polymers for Drug Delivery
Perhaps areas of research advancing the frontiers of 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 designed 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 drugs like polymer-protein and polymer-drug conjugates. The foremost recent developments in polymers capable of molecular recognition or leading object delivery unit of activity surveyed.
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Diffusion-Controlled Systems
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Solvent-Activated Systems
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Pharmacological Considerations in Drug Delivery
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Polymer-Drug Conjugates
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Molecularly Imprinted Polymers
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Polymer-Protein Conjugates
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Endosomolytic Polymer
Track 18: Polymers in Every Day Life
Futures of Bio-polymers demand the manufacturer for brand spanking new materials is overwhelming. Applications by the utilization of latest materials ought to utilize the properties of these polymers, and additionally the product ought to be developed based on those properties. The main issues for humans within the future are often energy & resources, food, health, mobility & infrastructure and communication. Synthetic polymers have since associate extend time compete a comparatively vital role in current medicative observations. Polymers occupy an outstanding role during this trendy 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 foremost advanced areas of analysis, chemical compound could be a basic part. Man synthesized artificial polymer mimicking the natural polymers, which is a group of molecules combined together.
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Aqueous dispersed media
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Radical polymerization
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Crosslinked nanoparticle
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Nano capsule
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Hyper branched polymer
Track 19: Recent Advances in Polymer Chemistry
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 beside the improvement of porosity and retention time. Among them, may be a perishable compound having versatile nature because of it’s a pair of element atoms connected on every sides of phosphorus atom of its chemical compound backbone, it can be easily replaced by nucleophilic substitution reaction. Plastic packaging for food and non-food applications is non-biodegradable, and additionally uses up valuable and scarce non-renewable resources like fuel.
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Inter facial Polymerization
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Polyaramids and Polyimides
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Enhanced tumor targeted gene delivery
Track 20: Polymers for Emerging Technologies
Polymers are multifaceted materials. This feature of polymer facilitates the people to manipulate the properties and behavior of the polymers according the requirement in the application area. This makes possible to provide a way to made polymer as a part in many trending inventions in medical, scientific, bio medical and electronics fields. In all such fields scientist have been combine the molecules of the polymers with other functional substances and produce a new featured polymer with desired features and properties.
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Information technology
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Nanotechnology
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Biotechnology
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Cognitive science
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Psych technology
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Robotics
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Artificial technology
Track 21: Polymers in Industries
Since the industry has witnessed a spectacular growth over the last six decades, the acceleration in consumption rates of plastics has taken place in many phases since warfare II. In areas of applications of plastics materials, a widely known long-standing example is electrical industries where the excellent combination of properties like insulation characteristics, toughness, durability, flame retardation capacity has led to increasing acceptance of plastics for plugs, sockets, wire and cable insulations and for housing electrical and equipment. The major compound targeting industries of this life includes building trade, packaging industries, in retorting methodology used for food method industries, wood-plastic composites, polymers in corrosion hindrance and control, piping systems, in automotive industries, in region industries and in electrical and electronic industries.
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Polymer characterization
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Conjugated polymers
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Supramolecular polymers
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Polymer Processing
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Polymer quench ants for Industrial Heat treatment
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Polyurethanes in cushioning, shoe sole
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Polyacrylates in paints and varnishes
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Polyesters in clothing and food packaging industries
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Silicone elastomers in cosmetics
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Thermoset resins for automotive, electronic, adhesives
Track 22: 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.
Track 23: Polymer Technology
Polymer Technology works with properties and assessment of polymeric materials properties, for example, mechanical properties and life length forecast. A significant piece of our work is the base for accreditation of items for use in various territories, from packages to buildings. Polymer Technology manages plastics in a wide range of angles. We assess the mechanical properties of polymeric materials and items strength in their current circumstance of utilization.
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Supramolecular Polymers and 3D Printing
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Polymer Design and Reaction
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Advanced polymer techniques
Track 24: Polymers in Medicine
In a traditional pharmaceutics area, such as tablet manufacturing, polymers are used as tablet binders to bind the excipients of the tablet. Modern or advanced pharmaceutical dosage forms utilize polymers for drug protection, taste masking, controlled release of a given drug, targeted delivery, increase drug bioavailability, and so on and so forth. Polymers have found application in liquid dosage forms as rheology modifiers.They are used to control the viscosity of an aqueous solution or to stabilize suspensions or even for the granulation step in preparation of solid dosage forms. Major application of polymers in current pharmaceutical field is for controlled drug release. In the biomedical area, polymers are generally used as implants and are expected to perform long-term service. This requires that the polymers have unique properties that are not offered by polymers intended for general applications. In general, the desirable polymer properties in pharmaceutical applications are film forming (coating), thickening (rheology modifier), gelling (controlled release), adhesion (binding), pH-dependent solubility (controlled release), solubility in organic solvents (taste masking), and barrier properties (protection and packaging).
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Polymers Application in Medicine, Health, Biotechnology and others
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Polymer Therapeutics: Concepts and Applications
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Polymers in Biotechnology, Medicine and Health
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Polymerization in Pharmaceutical Industry
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Therapeutic and Biomedical Devices
Track 25: Polymers and the Environment
Even beyond their persistence in oceans and water pollution from their production, synthetic polymers are a significant challenge on land because they are often disposed of in landfills where they will remain for centuries into the future slowly leaking toxins into soil as time passes. Biodegradable polymers are defined as Polymers comprised of monomers linked to one another through functional groups and are broken down into biologically acceptable molecules that are metabolized and removed from the body via normal metabolic pathways. The development of biodegradable polymer composites promotes the use of environmentally friendly materials. Most in the industry use the term bioplastic to mean a plastic produced from a biological source. All petroleum-based plastics are technically biodegradable. Biodegradable Polymers can also use to control the drug release rate from the formulations. Current and future developments in biodegradable polymers and renewable input materials focus relate mainly to the scaling-up of production and improvement of product properties resulting in increased availability and reduction in prices.
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Plastics, Biopolymers and their Environmental Impact
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Polymeric Waste
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Polymer Waste Management
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Biodegradable Plastics Applications
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Recycling and Waste Management of Biopolymers
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Green Composites in Biopolymers
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Recycling and Disposal of Polymers
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Solid waste management techniques of polymers
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Polymer Degradation and Stabilization
Market analysis
Euro Polymer Chemistry 2022 invites all of the great scientists, academicians, young researchers, Business delegates and students from all over the world to attend the 7th International Conference on Polymer Chemistry from October 10-11, 2022 at Berlin, Germany.
The organizing committee is gearing up for an exciting and informative conference program including plenary lectures, symposia, workshops on a variety of topics, poster presentations and various programs for participants from all over the world. It covers very global aspects on polymer from very fundamental issue to practical application of the principle of polymer Chemistry, anyone interested in future progress of Polymer technology should not miss.
We’re looking forward to an excellent meeting with great scientists from different countries around the world and sharing new and exciting results in polymer, which will be held in Berlin, Germany from October 10-11, 2022.
Scope of Polymer chemistry:-
Polymers are high molecular mass compounds formed by polymerization of monomers. The simple reactive molecule from which the repeating structural units of a polymer are derived is called a monomer. A polymer is chemically described by its degree of polymerization, molar mass distribution, tacticity, copolymer distribution, the degree of branching, by its end-groups, crosslinks, crystallinity and thermal properties such as its glass transition temperature and melting temperature. Polymers in solution have special characteristics with respect to solubility, viscosity and gelation.
Importance of Polymer Chemistry:-
Polymers and plastics are generally used in coating and packaging applications. Around 80% polymeric materials are produced from the petroleum industry, while processing fossil fuels. The burgeoning use of plastics is burdening the environment with its increasing carbon footprint due to greenhouse gas emissions, along with other factors such as soil and ground water pollution. Thus arising a need for environment-friendly alternatives. The growing focus towards sustainable development is expected to create an opportunity for bio-based plastics and polymers in the coming years. Governments are encouraging the use of biodegradable polymers over conventional polymers so as to reduce carbon footprint. Some major automotive companies are now opting for biopolymers in their vehicles. Polymers plays a vital role in our lives because of its uniqueness in properties and extended application in industries, packaging, sports, medicine, perfumes and preservatives, plastics, fuels, toys etc. Plastics are also used in the manufacture of Prosthetic devices and surgical equipment. Furthermore, polymer chemistry is quite a broad field and has expanded to include overlapping with biopolymeric materials and materials chemistry.
Industry Insights:-
The global polymer binders market size will grow by USD 14.21 billion during 2019-2023 at a CAGR of almost 8%. The increasing use of polymer binders in coating formulation and the growing demand for lithium polymer batteries are some of the factors expected to drive market growth. The report provides a detailed analysis of the market by application (architectural coatings, adhesives and sealants, textile and carpets, paper and board, and others) and region (APAC, Europe, MEA, North America, and South America). Also, the report analyzes the competitive landscape and offers information on several companies including Arkema Group, BASF SE, Celanese Corp., DowDuPont Inc., and Wacker Chemie AG.
Polymer binders are used to join two similar or different materials such as plastics, composites, and metals into a single unit. It helps in improving the durability, tensile strength, workability, and flexural strength of the substrate material.
Lithium polymer (LiPo) batteries are increasingly being preferred over lithium-ion batteries because of their higher energy density, design flexibility, and superior electrical performance. The anode coatings in these batteries are made from polymer binders which exhibit excellent adhesion, water absorption, recharging, ionic conductivity, and chemical resistance properties. The superior performance and small size of lithium polymer batteries make them ideal for use in smartphones, laptops, tablets, gadgets, smart watches, and navigation and tracking devices. The applications of lithium polymer batteries are expected to further expand to e-bikes, solar vehicles, and hoverboards in the coming years. This growing demand for lithium polymer batteries is identified as one of the critical polymer binders market trends, which will have a positive influence on the growth of the market
The increasing residential and infrastructural development across the world will boost the demand for industrial coatings. Polymer binders are increasingly being used for industrial and architectural coating applications as it exhibits superior adhesion and abrasion resistance in the waterborne coating formulation. Moreover, stringent regulations implemented by various countries to reduce volatile organic compounds (VOCs) emission during coating formulation will further boost the demand for waterborne coatings which have lower VOC emission and pose fewer health risks. Polymer binders are widely used in coating formulation to enhance the performance and durability of waterborne and solvent-borne coatings. The increasing use of polymer binders in coating formulation will be one of the significant factors influencing polymer binders market growth at a CAGR of almost 8% during the forecast period.
Application Insights:-
The application segment has been segregated into architectural coatings, adhesives and sealants, textile and carpets, paper and board, and others. The architectural coatings segment accounted for the highest polymer binders market share in 2018. During the forecast period, architectural coatings and textile and carpets segments will grow at a faster pace than the overall market. The adhesives and sealants, paper and board, and other segments will grow at a slower pace than the overall market.
Factors such as easy availability and pigment-bonding capacity are boosting the demand of acrylic-based polymer binders for architectural coating applications. The increasing use of environment-friendly polymer binders with low formaldehyde content to produce water-borne architectural coating will also contribute to the polymer binders market growth in this segment.
Regional Insights:-
APAC accounted for the highest market share in 2018. During the forecast period, the market’s growth in this region will be faster than the growth of the market in other regions. China is a key market for polymer binder in this region.
The growth of various end-user industries such as construction, textiles, and packaging in China, India, Japan, Indonesia, and South Korea will be one of the major factors fueling the growth of the polymer binders market in APAC. Infrastructure development, growing demand for paper-based packaging, and expansion of the textile industry are some of the factors which will create several growth opportunities for polymer binder vendors in this region.
Top Polymer Binder Manufacturers:-
The global polymer binders market is fragmented. To help clients improve their market position, this report provides an analysis of the market’s competitive landscape and offers information on the products offered by various companies. Moreover, this polymer binder market forecast report also includes information on the upcoming trends and challenges that will influence market growth. This will help companies create strategies to make most of the upcoming growth opportunities.
The report offers a detailed analysis of several leading polymer binder manufacturers, including:
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Arkema Group
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BASF SE
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Celanese Corp.
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DowDuPont Inc.
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Wacker Chemie AG
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Segments Covered in the Report:-
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Polymer binder market by application
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Architectural coatings
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Adhesives and sealants
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Textile and carpets
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Paper and board
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Others
Polymer binder market by region
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APAC
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Europe
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MEA
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North America
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South America
Key Highlights of the Polymer Binder Market Forecast Report for the Period 2019-2023
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CAGR of the market during the forecast period 2019-2023
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Detailed information on factors that will accelerate the growth of the polymer binder size during the next five years
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Precise estimation of the global polymer binder market worth and its contribution to the parent market
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Accurate predictions on upcoming trends and changes in consumer behavior
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The growth of the polymer binder industry across APAC, Europe, MEA, North America, and South America
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A thorough analysis of the market’s competitive landscape and detailed information on several vendors
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Comprehensive details of factors that will challenge the growth of polymer binder companies
Conference Highlights:-
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Polymer Chemistry
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Polymer Synthesis
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Polymer Engineering
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Polymeric Materials
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Polymerization Catalysis
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Polymers in Every Day Life
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Polymer Nanotechnology
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Polymers for Drug Delivery
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Recent Advances in Polymer Chemistry
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Polymers for tissue engineering
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Polymers and the Environment
Societies Associated with Polymer Chemistry:-
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Asociacion Nacional de Quimicos de Espana (ANQUE)
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Biochemical Society
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Chemical Institute of Canada
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Canadian Society for Chemistry
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Chemical Industries Association
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Chemical Society of Japan
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Chemical Structure Association Trust
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Societe Chimique de France
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Israel Analytical Chemistry Society
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Japan Society for Analytical Chemistry
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Polymer Society of Korea
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Portuguese Chemical Society
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The Royal Swedish Academy of Sciences
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Royal Netherlands Chemical Society (KNCV)
Major Marketing Associations of Polymer Chemistry around the Globe:-
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British Plastics Federation
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European Council for Plasticizers and Intermediates
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American Coatings Association
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American Chemical Society (Division of Polymer Chemistry)
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American Physical Society Division of Polymer Physics (APS DPOLY)
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Polymer Division of the Royal Australian Chemical Institute (RACI Polymer Division)
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Belgian Polymer Group (BPG)
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Brazilian Polymer Association
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European Polymer Federation
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Bioenvironmental Polymer Society
Target Audience:-
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Materials Scientists/Research Professors
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Junior/Senior research fellows of Materials Science/ Nanotechnology/ Polymer Science
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Material science / Nanotechnology / Polymer/ Chemical Companies
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Material science / Nanotechnology Associations
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Advanced Materials and Nanotechnology Engineers
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Physicists/Chemists
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Biotechnology