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Exploring Recent Advances and Applications in Polymer Chemistry
- Polymer Chemistry 2019

Welcome message


 Polymer Chemistry invites all the participants from all over the world to attend “2nd International Conference on Chemistry and Polymer Chemistry” during May 20-21,2019 | Rome, Italy which includes prompt 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 Chemistry 2019 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 test 123                                         

About Conference




Polymer Chemistry 2019 is a global overview the theme: “Exploring recent advances in polymer chemistry, related fields and applications” is designed for professionals at all levels and career phases of the plastics industry, who want to improve their understanding of what will drive and shape the future of the market. This will include senior executives, sales and marketing personnel, strategic planners, who will benefit from a broad overview of the polymer industry.

The strength of the Conference is that the participants tend to include all phases of the value chain as well as individuals from a wide variety of sector and countries. This experience helps the Conference to be an interactive forum and encourages a strong level of dialogue and discussion, thus maximizing the benefits of attendance. This conference surely provides better information and insight into the development of the world polymer industry, which in turn has enabled attendees to make better and more profitable decisions.


Polymer Chemistry 2019 is a platform to achieve the prevailing gaps in the transformation of this multidisciplinary science of hope, to serve promptly with solutions to all in the need. Satellite 2019 will have an anticipated participation of 120+ delegates across the world to discuss the purpose of the conference.

Target Audience:

·         Eminent personalities

·         Directors/Managers

·         Head of Departmental

·         Presidents/Vice Presidents

·         CEO's of biotech companies

·         Professors, Associate and Assistant professors

·         Doctors

·         Research Scholars and students from the related fields

·         Other experts in Polymer Chemistry 


1) All 2 days programs

2) Reception banquet

3) B2B meetings
4) A free paper abstract in our Journal for free of cost
5) Accepted Abstracts will be published in respective supporting journals, each abstract will be labeled with a DOI provided by Cross Ref.
6) Certificate of presentation by International Organizing Committee (IOCM)
7) Can attend all the Interactive sessions and Workshops
8) All attendees can avail CPD Credits (Continuing Professional Development) by attending our prestigious conference.
9) Career Guidance Workshops to the Graduates, Doctorates and Post-Doctoral Fellows
10) 2 days Lunch during the conference
11) Coffee break during the conference
12) Conference Kit
Package A Benefits:
1)Accommodation for 2 nights(May 19 &May 20) at Conference Venue
2)Above all Registration Benefits
3)Free access to Wi-Fi
Package B Benefits:
1)Accommodation for 3 nights(May 19,20&21) at Conference Venue
2)Above all Registration Benefits
3)Free access to Wi-Fi

Market Analysis

Importance and Scope: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. Polymer chemistry or macro molecular chemistry is concerned with the chemical synthesis and chemical properties of polymers. Polymer chemistry is a multidisciplinary science that deals with the chemical synthesis and chemical properties of polymers which were considered as macro molecules. 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 bio polymeric materials and materials chemistry.The diversity of use is growing day by day. The history of Bio polymer is not a long one. They are beginning to emerge as a result of needing to be more responsible in taking care of the world we live in. Thus, the recent emergence of bio-based products rather than petroleum or natural gas based products. Various reasons are associated with the research and development of Bio polymers. The use of bio polymers could markedly increase as more durable versions are developed, and the cost to manufacture these bio-plastics continues to go fall. Bio-plastics can replace conventional plastics in the field of their applications also and can be used in different sectors such as food packaging, plastic plates, cups, cutlery, plastic storage bags, storage containers or other plastic or composite material items you are buying and therefore can help in making environment sustainable.

Market Analysis:

The global polymer industry is expected to grow with a CAGR of 8.5%. over 2017-2022. 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.The plastic antioxidants market by Polymer Resin is estimated to be USD 1.69 billion in 2017 and is projected to reach USD 2.11 billion by 2022, at a CAGR of 4.5% from 2017 to 2022.The global market for water-soluble polymers was valued at around $35.7 billion in 2016. This market will grow from nearly $37.4 billion in 2017 to $49.6 billion by 2022 with a compound annual growth rate (CAGR) of 5.8% for the period of 2017-2022.According to ‘Global Hair Fixative Polymers Market, By Type, By Application, By Region, Competition Forecast & Opportunities, 2012-2022’, global hair fixative polymers market is projected to witness significant growth through the forecast period, surpassing 29 thousand metric tons in volume terms by the end of 2022. The global hair fixative polymers market is projected to grow at a CAGR of around 8% during 2017-2022 owing to growing preference for on-the-go hair styling products and rising per capita expenditure across the globe.

Polyolefin foam (PO) is the fastest-growing type of polymer foam. The market size of polymer foam was estimated at USD 94.86 billion in 2017 and is projected to reach USD 126.08 billion by 2022, at a CAGR of 5.86% from 2017 to 2022. PO is the fastest-growing type of polymer foam because of its resilience. It is an excellent energy absorber, making it useful in cushion packaging, athletic pads, floatation devices, and occupant safety applications. It offers flexibility, cushioning properties, toughness, good chemical and abrasion resistance, electrical and thermal insulation, and compression set properties.Biodegradable Polymers Market Report by Material, Application, and Geography – Global Forecast to 2021 is a professional and in-depth research report on the world's major regional market conditions, focusing on the main regions (North America, Europe and Asia-Pacific) and the main countries (United States, Germany, United Kingdom, Japan, South Korea and China).

 Major Marketing Associations of Polymer Chemistry around the Globe

  • British Plastics Federation
  • European Council for Plasticizers and Intermediates
  • American Coatings Association
  • American Chemical Society (Division of Polymer Chemistry)
  • American Physical Society Division of Polymer Physics (APS DPOLY)
  • Polymer Division of the Royal Australian Chemical Institute (RACI Polymer Division) 
  • Belgian Polymer Group (BPG)
  • Brazilian Polymer Association
  • European Polymer Federation
  • Bioenvironmental Polymer Society

Major Marketing Associations and Societies in Canada and USA

  • The Canadian Plastics Industry Association (CPIA)
  • Chemistry Industry Association of Canada
  • The Institute of Materials, Minerals and Mining (IOM3)
  • Division of Polymer Chemistry Inc., American chemical Society
  • American Plastics Council (USA)
  • Society of Plastics Engineers (USA)
  • Society of the Plastics Industry (USA)

Target Audience:

Eminent Scientists/Research Professors, Junior/Senior research fellows, Students, Directors of companies, Engineers, Members of different physics associations.

Top Universities :

  • University of Waterloo's Institute for Polymer Research (IPR)
  • University of British Columbia
  • Simon Fraser University
  • University of California
  • Stanford University
  • Harvard University
  • University of Massachusetts Amherst
  • Massachusetts Institute of Technology (MIT)
  • North-eastern University
  • Boston University
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


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.

       Track 1-1 Nonlinear Polymerization

       Track 1-2 Polysiloxanes  and Lac-tams
       Track 1-3 New "one-pot" Approaches to Hyperbranched Species
       Track 1-4 Polypeptide Synthesis
       Track 1-5 Inter facial Polymerization

       Track 1-6 Polyaramids and Polyimides
       Track 1-7 Synthesis of polyurethane foams
       Track 1-8 Polyamides and Common Polyesters

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.
       Track 2-1 Segmented and Block Copolymers
       Track 2-2 Interchange Reactions
       Track 2-3 Kinetics and Equilibrium
       Track 2-4 Types of Monomers
       Track 2-5 Bulk Polymerization

       Track 2-6 Polymerization's/Condensation Polymerization's
       Track 2-7 Polymer analogs reactions

Track 3: Polymer Physics and Characterizations
Polymer Physics is the field of physics that studies polymers, their fluctuations, mechanical properties, as well as the kinetics of reactions involving degradation and polymerization of polymers and monomers respectively. While it focuses on the perspective of condensed matter physics, polymer physics is originally a branch of statistical physics. Polymer physics and polymer chemistry are also related to the field of polymer science, where this is considered the applicative part of polymers. Polymer Characterization includes determining molecular weight distribution, the molecular structure, the morphology of the polymer, Thermal Properties, mechanical properties, and any additives. Molecular Characterization also includes the development and refinement of analytical methods with statistical models which help to understand phase separation and phase transitions of polymers. The results achieved hereof can be eventually applied to optimize the experimental conditions during analyses. We have multiple approaches for Polymer Characterization.
         Track 3-1 Size exclusion chromatography
         Track 3-2 Polydispersity
         Track 3-3 Adsorption and wetting behavior of polymers

         Track 3-4 Degradation and thermal behavior of polymers
         Track 3-5 Polymer Networks and Polymer blends
         Track 3-6 Semi flexible Polymers
         Track 3-7 Static light scattering techniques
         Track 3-8 Colligative property measurements
         Track 3-9 Diffusion of polymers
         Track 3-10 Viscometry
         Track 3-11 Computational Science

 Track 4: 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 4-1 Polypyrrole chains and Optical interactions
        Track 4-2 Polymer conductive s

        Track 4-3 Electro-active Polymers
        Track 4-4 Radical Copolymerization

        Track 4-5 Isomerism of Polymers
        Track 4-6 Investigating surface properties of functional polymers

 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.
        Track 5-1 Biodegradable Polymer Applications
        Track 5-2 Biodegradable Polymers for Industrial Applications
        Track 5-3 Advanced Biodegradable Polymers  
        Track 5-4 Petrochemical Products
        Track 5-5 Biocomposites

        Track 5-6 Graphene Nanocomposites
        Track 5-7 Biotechnology

 Track 6: 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 6-1 Biomimetic materials
        Track 6-2 Liquid Crystal (LC) Polymers
        Track 6-3 Biomaterials Systems
        Track 6-4 Polysaccharides
        Track 6-5 Polypeptides
        Track 6-6 Polynucleotides
        Track 6-7 Electrospun materials

Track 7: Polymer Engineering
Polymer Engineering is generally an engineering field that designs, analyses, and/or modifies polymer materials. Polymer engineering covers aspects of a number of subtypes the petrochemical industry, polymerization, structure and characterization of polymers, properties of polymers, compounding, and processing of polymers and description of major polymers, structure-property relations, and applications in Polymer Engineering.
        Track 7-1 Polymer characterization
        Track 7-2 Naturally Occurring Zein
        Track 7-3 Structure and mechanical properties of polymers
        Track 7-4 Conjugated polymers
        Track 7-5 Supramolecular Polymers
        Track 7-6 Polymer Processing

Track 8: Polymers for Emerging Technologies
The early developments in Polymer Technology occurred without any real knowledge of the molecular theory of polymers. The idea that the Structure of Molecules in Nature might give an understanding of plastics was put forward by Emil Fischer, who in 1901 discovered that natural polymers were built up of linked chains of molecules. It was not until 1922 that the chemist Herman Staudinger proposed that not only were these chains far longer than first thought, but they were composed of giant molecules containing more than a thousand atoms.
        Track 8-1 Polyvinyl Chloride Via Precipitation Polymerization
        Track 8-2 Suspension (Bead) Polymerization Processes
        Track 8-3 Emulsion Polymerization Processes

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 9-1 Catalysis and Polymers group
        Track 9-2 Oxophilic Organometallics
        Track 9-3 Acid-Base Bifunctional Catalysts on Polymer Supports

        Track 9-4 Catalysis on specific polymer surfaces and in molecular imprints
        Track 9-5 Ziegler-Natta Catalysis

Track 10: 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 10-1 Coatings
       Track 10-2 Oil Industry
       Track 10-3 Cosmetics
       Track 10-4 Plastics
       Track 10-5 Fibers

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 also 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 11-1 Biodegradable Plastics
       Track 11-2 Benefits of bioplastics
       Track 11-3 Innovations in Food Packaging
       Track 11-4 Environmental impact
       Track 11-5 Poly-3-hydroxybutyrate (PHB)
       Track 11-6 Polylactic acid (PLA)

       Track 11-7 Synthetic Biology
       Track 11-8 Bio-Based Plastics
       Track 11-9 Polyethylene

Track 12: Polymer Nanotechnology
Polymeric Nanoparticles are predominantly prepared by wet synthetic routes. Several industrial processes will be described. Emphasis will be placed on the type of polymers and morphology structures that can be synthesized using each process. Controlled radical polymerization will be explored for their ability to provide structural control of polymer chains. The extraordinarily large surface area on the nanoparticles presents diverse opportunities to place functional groups on the surface. Particles can be created that can expand/contract with changes in pH, or interact with antibodies in special ways to provide rapid ex-viva medical diagnostic tests. Important extensions have been made in combining inorganic materials with polymers and in combining different classes of polymers together in nanoparticle form.
         Track 12-1 Advance technology of Nanotechnology in Polymer Chemistry
         Track 12-2 Polymer nanocomposites matrices
         Track 12-3 Tissue engineering
         Track 12-4 Nanoelectronics & Photonics
         Track 12-5 Block Copolymer Nanocomposites
         Track 12-6 Polymer films
         Track 12-7 Engineered Nanomaterials and their applications
         Track 12-8 Nanomedicine and Nanotoxicity

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 13-1 Global Bio-based Market Growth of Biopolymers
         Track 13-2 Nanoscience and Nanotechnology
         Track 13-3 Biopolymers in Drug Delivery
         Track 13-4 Ceramics and Applications
         Track 13-5 Elastomers

Track 14: Polymer Science
The foremost challenges in the upcoming decades will be the increase in population, the concentration of people in expansive urban centers, and globalization, and the expected change of climate. Hence, the main concerns for humans in the future will be energy & resources, food, health, mobility & infrastructure, and communication. There is no doubt that polymers will play a key role in finding successful ways of handling these challenges. Polymers will be the material of the new millennium and the production of polymeric parts i.e. green, sustainable, energy-efficient, high quality, low-priced, etc. will assure the accessibility of the finest solutions around the globe... Synthetic polymers have since a long time played a relatively important role in present-day medicinal practice. Many devices in medicine and even some artificial organs are constructed with success from synthetic polymers.
         Track 14-1 Polymer structure and sub-atomic course of action
         Track 14-2 Polymer characteristics 
         Track 14-3 Polymer mixes
          Track 14-4 Strong Waste Management

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, non-equilibrium 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 15-1 Mechanics of materials
         Track 15-2 Graphene material science
         Track 15-3 Modern materials chemistry
         Track 15-4 Applied physics

Track 16: Solid Waste Management of Polymers
The controlled combustion of polymers produces heat energy. The heat energy produced by the burning plastic municipal waste not only can be converted to electrical energy but also helps burn the wet trash that is present. Paper also produces heat when burned, but not as much as do plastics. On the other hand, glass, aluminum, and other metals do not release any energy when burned. The disposal of polymer solid waste by means other than landfilling is necessary.

                   Track 16-1  Recycling of plastic waste by density separation
                   Track 16-2  Polymers in plastic industry
                   Track 16-3  Growth opportunities in shifting polymers markets
                   Track 16-4  Industry profitability for investments on polymer

          Track 17: Chemistry of industrial polymers
          The atoms making macromolecules are held together by covalent substance bonds, shaped by the sharing of electrons. Singular particles are additionally pulled in to each other by electrostatic powers, which are significantly weaker than covalent bonds. These electrostatic powers increment in greatness, be that as it may, as the span of the particles increments.

                          Track 17-1 Rubber and Plastic Bonding, Repair, and Restoration
                          Track 17-2 Glass and Ceramics Repair and Bonding
                          Track 17-3 Concrete Modification, Protection, and Repair
                          Track 17-4 Masonry and Wood Protection and Repair
                          Track 17-5 Metal Protection and Repair

                    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.

                                 Track 18-1 Synthetic biodegradable polymers
                                 Track 18-2 Nanofibrous scaffolds
                                Track 18-3 Polymers for solid-state porous scaffolds

                          Track 19: Bio-polymers vs. Synthetic polymers
                          A noteworthy characterizing contrast amongst biopolymers and manufactured polymers can be found in their structures. All polymers are made of redundant units called monomers. The correct concoction synthesis and the succession in which these units are orchestrated are known as the essential structure, on account of proteins. Auxiliary science is the investigation of the basic properties of the biopolymers. Conversely, most manufactured polymers have considerably easier and more irregular structures. This reality prompts an atomic mass appropriation that is absent in biopolymers. Truth is told, as their blend is controlled by a format coordinated process in most in viva frameworks, all biopolymers of a sort (say one particular protein) are on the whole indistinguishable: they all contain the comparable successions and quantities of monomers and in this manner, all have a similar mass. This wonder is called mono disparity as opposed to the poly disparity experienced in manufactured polymers.

                                       Track 19-1 Environmental impacts
                                       Track 19-2 Structural characterization
                                       Track 19-3 Conventions and nomenclature
                                Track 20: Macromolecular Engineering
                                The process of designing and synthesizing well-defined complex macromolecular architectures. This process allows for the control of molecular parameters such as molecular-weight/molecular-weight distribution, microstructure/structure, topology, and the nature and number of functional groups. In addition, macromolecular engineering is the key to establishing the relationships between the precise molecular architectures and their properties. The understanding of the structure-property interplay is critical for the successful use of these elegantly tailored structures in the design of novel polymeric materials for applications such as tissue engineering, drug delivery, molecular filtration, micro- and opts electronics, and polymer conductivity. Complex architectures, including star-shaped, branched, grafted, and dendrite-like polymers, have been prepared using living polymerization methods (for which there is no termination step to stop chain growth) such as anionic, cationic, living radical, metal-catalyzed polymerization, or combinations of these methods.

                                                   Track 20-1 Anionic polymerization
                                                   Track 20-2 Living radical polymerization
                                                   Track 20-3 Catalytic polymerization's
                                                   Track 20-4 Combinations of techniques
                                                   Track 20-5 Links to Primary Literature

                                            Organizing Committee
                                            OCM Member
                                            Bing huei chen
                                            Fu Jen Catholic University
                                            New Taipei City, China
                                            OCM Member
                                            Eliade Stefanescu
                                            Advanced Studies in Physics Center of the Romanian Academy
                                            Bucharest, Romania
                                            OCM Member
                                            CEO , polymer
                                            P.G.Center, GSC Chitradurga
                                            Bengaluru, India
                                            OCM Member
                                            Rosa Lelyana
                                            Diponegoro University
                                            Sumatra, Indonesia
                                            OCM Member
                                            Yavuz Selim S?lay
                                            Istanbul Consulting Group
                                            Istanbul, Turkey
                                            OCM Member
                                            Mauricio Vásquez-Rendón
                                            Instituto Tecnológico Metropolitano, Medellín, Colombia
                                            Bogota, Colombia
                                            OCM Member
                                            Birbal Bajia
                                            Panipat Refinery and petrochemical complex
                                            chandigarh, India
                                            Renowned Speakers
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                                            Transfer of registration

                                            All fully paid registrations are transferable to other persons from the same organization if the registered person is unable to attend the event. Transfers must be made by the registered person in writing to Details must be included the full name of replacement person, their title, contact phone number, and email address. All other registration details will be assigned to the new person unless otherwise specified.

                                            Registration can be transferred to one conference to another conference of Allied Academies Ltd if the person is unable to attend one of the conferences.

                                            However, Registration cannot be transferred if it is intimated within 14 days of the respective conference.

                                            The transferred registrations will not be eligible for Refund.

                                            Visa Information

                                            Keeping in view of increased security measures, we would like to request all the participants to apply for Visa as soon as possible.

                                            Allied Academies Ltd will not directly contact embassies and consulates on behalf of visa applicants. All delegates or invitees should apply for Business Visa only.

                                            Important note for failed visa applications: Visa issues cannot come under the consideration of cancellation policy of Allied Academies Ltd, including the inability to obtain a visa.

                                            Refund Policy:

                                            If the registrant is unable to attend and is not in a position to transfer his/her participation to another person or event, then the following refund arrangements apply:

                                            Keeping in view of advance payments towards Venue, Printing, Shipping, Hotels and other overheads, we had to keep Refund Policy is as following slabs-

                                            • Before 90 days of the conference: Eligible for Full Refund less $100 Service Fee
                                            • Within 90-60 days of Conference: Eligible for 50% of payment Refund
                                            • Within 60 days of Conference: Not eligible for Refund
                                            • E-Poster Payments will not be refunded.

                                            Accommodation Cancellation Policy:

                                            Accommodation Providers (Hotels) have their own cancellation policies, and they generally apply when cancellations are made less than 30 days prior to arrival. Please contact us as soon as possible, if you wish to cancel or amend your accommodation. Allied Academies Ltd will advise the cancellation policy of your accommodation provider, prior to canceling or amending your booking, to ensure you are fully aware of any non-refundable deposits.

                                            Authorization Policy

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