2nd International Experts Meeting On Advances in Materials Science Research and Nanotechnology

Osaka, Japan   October 29-30, 2018

Materials Science 2018

Osaka, Japan October 29-30, 2018

Theme: Modernization of Materials Science and Nanotechnology

Meetings International proudly announces the 2nd International Experts Meeting On Advances in Materials Science Research and Nanotechnology (Materials Science 2018) scheduled during October 29-30 2018 at Osaka, Japan. With a theme of “Modernization of Materials Science and Nanotechnology". The conference provides a Global Platform for Pharma, Biotech, Medical and Healthcare Professionals to Exchange Ideas, Knowledge and Networking at its 100+ International Conferences.

Materials are chain-like molecules made up of repeating chemical blocks and can be very long in length. Depending on the nature of the repeating unit they are made of polysaccharides, proteins of amino acids, and nucleic acids of nucleotides. The studies are more concerned to Green Composites, Biopolymer Feed Stock Challenges, Bio fibers & Microbial Cellulose, Biomaterials and Bio plastics. Advanced studies are being made to improvise developments in Biopolymer Technology, Waste Management, pharmaceutical and biomedical applications, Biodegrade ability, and many more.

Materials Science 2018 will bring together key decision makers and innovators within this rapidly growing field. This intensive 3-Day program will examine various Biopolymer strategies. The event will cover Materials Science, Polymers, Biopolymers, Advanced Biopolymers, Biodegradable Polymers, Bio Renewable Biopolymers, Biopolymers as Materials, Polymeric Biomaterials etc.

Importance and Scope:

Over the past few years, global economic activities have increased a lot. This tremendous growth has raised serious problems about current important patterns of production and consumption. As the current society has increased its attention in understanding of the environmental aspects and its industrial practices, greater attention has been given to the concept of sustainable economic systems that rely on energy from undepletable source and materials. The use of biologically derived Polymers become as an important component of this global world.

Meetings International Materials Science Meeting will offer you an unmatched attendee experience. In addition to the many scientific sessions and take-home case study examples, you will leave this event with many other novel development strategies from some of our workshops and symposiums. Engage in dynamic conversation with your industry peers at our multiple networking sessions, and takeaway novel drug development and commercialization strategies, which could speed up time to market and save your organization millions. We hope you will join us in Osaka, Japan this October to enhance your drug delivery capabilities, and increase time to market on therapeutics.

Sincerely,

Operating Committee

CEO and Founder

Meetings International PTE LTD

Track 1: Nanotechnology in materials science

This session offers a strong introduction to fundamental concepts on the source of material science. It delivers the central issues of materials science, and includes innovative research on Atomic and Nano structures and also micro and macro structures. The fundamentals of material science also deal with the Crystallography, bonding properties, material synthesis and with thermodynamic and kinetic properties.

Track 2: Bionanotechnology and Nanomedicine

The Materials in research presents several important topics on Nanomaterials and Biomaterials. It deals with developments and challenges in Electronic, Optical and Magnetic Materials and prospects that have increased from Computational Materials Science and Materials Theory. The developments of surface science and engineering are also discussed in this session.

Track 3: Materials Science & Engineering

Materials Science provides a comprehensive theoretical and practical review of advanced materials design and processing. The research on electronic and photonic materials is the base of devices which exploit electric charge or light which delivers faster and cheaper equipment’s for communication and information technologies. Nanotechnology is defined by the National Nanotechnology Initiative, in this theory the materials are engineered from any chemical substance, semiconductor Nano crystals, carbon fullerenes and organic dendrimers. Nanoscale materials seem in trade as consumer and industrial products and similarly as Novel drug delivery formulations. The concept of polymers and soft materials comprise of computational, theoretical and experimental approaches.

Track 4: Materials in Industry

Material science has numerous applications which include polymer materials, ceramics and composites. Glasses and ceramics use covalent and ionic-covalent types with SiO2 as a base for bonding. Ceramics are as soft as clay or as hard as stone and concrete and crystalline in form. Most of the glasses have a metal oxide merged with silica. To gorilla glass steel reinforced concrete is a structural element with wide range of applications. Plastics Material is manufactured by raw materials of polymers. Sphere plastics are materials with unique characteristics, such as ultra-high strength, electrical conductivity, electro-fluorescence and high thermal stability. Plastics are divided on the basis of its properties and applications. Carbon fiber strengthened plastic market reached $17.3 billion in 2014, and further the market is estimated to grow at a five-year CAGR (2015 to 2020) of 12.3%, to reach $34.2 billion in 2020. The competition in the global carbon fiber and carbon fiber reinforced plastic market is intense within a few large players, such as Toray Toho, Mitsubishi, Hexcel, Formosa, SGL carbon, Cytec, Hyosung, etc.

Track 5: Materials for Energy and Applications

Energy and sustainability are currently driving science and technology. Concerns on environment and the source of fossil fuel driven researchers to explore technological solutions with alternative forms of energy resource and storing. New materials and material assemblies are the core of this research undertaking. Fuel cells are used in the generation of materials energy. The development and discovery of new materials is intimately connected for the search of cleaner, smaller, cheaper and more efficient energy technologies. The assembly emphases on materials-based solutions to the energy problem through a series of case studies exemplifying improvements in energy-related materials research. Battery technology is strapped more in electric vehicle applications, which need more lightweight, high voltage and fast charging batteries. Solar thermal energy is different from Solar panel or photovoltaic technology. Heat is created by the light from the sun in concentration with solar thermal electric energy generation. Photovoltaic energy converts the sun’s light directly into electricity.                

Track 6: Materials Chemistry and Analysis

The basic vision of Materials for Energy Applications is to enable a changeover to energy system and to create world-recognised assistances in the field of energy applications by fundamental materials research. Biopolymers occur in nature, carbohydrates and proteins are the examples of biopolymers. Organ Implants are used for the transplantation of organs in humans. The profile supports interactions between resources for harvesting, passage and storage, and transformation of energy, and strives to reduce the distance between research and submissions. The Materials for Energy Applications profile comprises many prominent research leaders that are at the research front of their corresponding fields. The terms like bio polymeric materials and organ implants also comes under the category of materials for energy applications. Biomineralization is defined as the creation of inorganic materials with complex form in all groups of organisms from prokaryotes.

Track 7: Materials for Green Technology

Green technology incorporates a constantly developing group of procedures and materials from techniques for creating energy to non-toxic cleaning products. At present the expectation of this field is to bring innovation and changes in daily life of similar scale to the information technology evolution over past two decades. Sustainability is meeting the needs without conceding the capability of future generations to meet their own requirements. The reduction of waste and pollution by the change in patterns of consumption and production is termed as source reduction. To reduce the use and generation of hazardous substances the invention, design and application of chemical products is known as Green chemistry.

Track 8: Nanotechnology in Polymers

The Interesting things about nanotechnology are that properties of materials change when the size scale of their dimension reaches nanometers. Manufacturing of materials at Nanoscale is done by material scientists to understand the property changes. The field of material science includes characterization and properties of Nanoscale materials. Carbon nanotubes are concerned to the elegance of many scientists worldwide. The small proportions, strength and the outstanding physical properties of these arrangements make them very unique material with a whole range of auspicious applications. The prominence in application of computational methods in discovering various sizes of fullerenes and their isomers is given. The theory of isolated pentagon rule in fullerene chemistry has been publicized. Nanophotonics collects a large group of faculty members to raise new ideas and to carry out collective research with enhanced stimulation.

Track 9: Nanostructures and Nanofabrications

Chemical Vapour Deposition has the ability to produce various types of catalytically attractive nano-scale structures by altering the surface assets of massive or even nano-divided substrates. Comparatively new processes such as catalytic, fluidized-bed, rotary, two-step and large spot laser CVD allow the creation of nanoparticles, nanotubes, nanofibers and oriented films. Intensive research is being performed on the production and the preparation of supported catalysts by CVD. Graphene nanofibers are materials that show amazing properties appropriate for a number of progressive energy storage devices as well as chemical procedures. These solids deal with the direct route for the production of large quantities of high quality Graphene. The cost of manufacturing these supplies on a marketable scale presents a major challenge, which we have pursued to overcome via the usage of natural gas as a source of carbon. Catalysts are divided in to two types homogeneous and heterogeneous. The substance that is constant in composition is termed as homogenous mixture, whereas heterogeneous catalysts are solids that are supplemented in to gas or liquid reaction mixtures.

Track 10: Nanotechnology for biological system

Nanotechnologies use very small substances or artefacts. Nanomaterials are an increasingly vital product of nanotechnologies. They have nanoparticles, smaller than 100 nanometres in at least one element. Nanomaterials are evolving into use in healthcare, electronics, cosmetics and other areas. They call for specialized risk assessment of physical and chemical properties often differ from bulk materials, which cover health risks to consumers and workers and also potential risk to the environment. Increased relative surface and quantum effects are the two principal factors cause the properties of nanomaterial’s to differ from other materials. These factors can enhance properties such as reactivity, electrical characteristics and strength. Nanoparticles have a high surface area per unit mass when compared with larger particles. In living systems natural enzymes play vibrant roles in biological reactions.

Track 11: Polymeric materials and Nano Robotics

The assistance of metallurgy and materials science in the growth of solid-state electronics involves growth of high-purity, macroscopically dislocation-free silicon crystals; elimination of electro migration in thin metallic conductors and minimization of growth and processing induced defects in silicon. Nano structured and ultrafine materials includes properties such as nanostructured oxide dispersion strengthened alloys, ultra-fine grained high strength aluminium alloys through cryo-rolling and severe plastic deformation, lead-free nanostructured ferroelectric materials, production of bulk nanostructured materials and Synthesis of nanoparticles. Composite based materials like carbon nanotube composites and Aluminium matrix composites, high cycle fatigue of repair welds of AISI 410 stainless steels and Notch creep-rupture life of 718 super alloys.

Track 12: Nanotechnology in communications & Information Technology

Polymeric Materials deals with the subject areas of Material Science and Organic Chemistry. A polymer is a large macromolecule, composed with millions of recurrent linked units, each is relatively light and simple molecule. Due to their wide range of properties, both synthetic and natural polymers play crucial and abundant role in everyday life. Most similar classes of polymers are composed of hydrocarbons, mixtures of carbon and hydrogen. These polymers are specially made of carbon atoms bonded together into long chains that are termed as the backbone of the polymer. Due to the nature of carbon, one or more other atoms should be attached to each carbon atom in the backbone. These are the polymers that hold only carbon and hydrogen atoms. Other mutual polymers have backbones that comprise elements other than carbon. Nylons have nitrogen atoms in the replication unit backbone. Polyesters and polycarbonates comprise oxygen in the backbone. Scientists and engineers are constantly manufacturing more useful materials by deploying the molecular structure that marks the final polymer produced. Manufacturers and processors host various fillers, reinforcements and flavours into the base polymers, increasing product possibilities.

Track 13: Metallurgy and Materials Science

A large amount of our work emphases on materials that can stimulate helpful biological responses from the body, such as the stimulation of tissue repair. Tissue manufacturing has the potential to achieve this by uniting materials design and manufacturing with cell therapy. Biomaterials can deliver physical supports for plotted tissues and powerful topographical and chemical signs to guide cells. Biomaterials manufacturing contains synthesis, processing, and description of novel materials, comprising polymers, proteins, glasses, cements, composites and hybrids. Presenting nanoscale signs such as nanotopography or nanoparticles as therapeutic agents deliver an exciting approach to moderate cell performance. In order to probe the cell-material interface, we are establishing new analytical and non-invasive methods such as high resolution electron microscopy and live cell bio-Raman micro-spectroscopy. Also developing new synthetic biocompatible polymeric materials with unparalleled function and penetrating their biological efficiency.

Track 14: Biomaterials and Tissue Engineering

Advances in Materials science are used for studying the relationship between structure, properties, and uses of materials. The themes are seen from international and interdisciplinary viewpoints covering areas with metals, ceramics, glasses, polymers, electrical materials, composite materials, nanostructured materials and biological and biomedical materials. It aims to be the important source of primary communication for scientists examining the structure and properties of all manufacturing materials. The advances that transformed all our daily lives and have completely changed the research arena are: The International Technology Roadmap for Semiconductors, Scanning probe microscopes, Giant magneto resistive effect, Semiconductor lasers and light-emitting diodes, National Nanotechnology Initiative, Carbon fiber reinforced plastics, Carbon nanotubes, Soft lithography and Metamaterials.

Track 15: Advances in Materials Science

The aim of Computational Materials Science is to report on outcomes that deliver new perceptions into, or considerably accepting the properties of materials or phenomena related with their design, synthesis, processing, description, and operation. Simulation of finite systems and electronic structure methods comes under computational materials science. Interatomic models are also termed as force fields. All features of modern materials modelling are of interest, together with quantum chemical methods, density functional theory, semi-empirical and classical approaches, statistical mechanics, atomic-scale simulations and phase-field techniques. To study the physical moments of atoms and molecules the computer simulation method of molecular dynamics is used.


Track 16: Nanoelectronic devices

Electronic and Magnetic materials research unites the essential values of solid state physics and chemistry, of electronic and chemical manufacturing of materials science. Molecular interactions are also known as intermolecular interactions or noncovalent interactions which are not chemical reactions. The process of melting, unfolding, strand separation, boiling and disassembly involves changes in molecular interactions. The time dependence and rigid rotation are basic parameters of electronic and magnetic materials. Molecular dynamics is a type of N-body simulation. It is a computer simulation method to identify the physical movements of atoms and molecules allowed to interact for a given period of time to produce dynamic evolution of the system.  

Track 17: Electronic and Magnetic Materials

The nano-composite material has widened significantly to include a large selection of systems such as one-dimensional, two-dimensional, three-dimensional and amorphous materials, made of particularly different components and mixed at the nanometer scale. The nanocomposite materials are fast growing area of research. Substantial effort is concentrated on the ability to obtain control of the nanoscale structures via advanced synthetic methods. The assets of nano-composite supplies depend not only on the properties of their distinct parents but also on their morphology and interfacial features. This quickly increasing field is producing many rousing new materials with original properties. They can originate by uniting properties from the parent elements into a single material. There is also the opportunity of new properties which are unidentified in the parent essential materials.

Track 18: Mechanical application of Nanotechnology

Electronic and Magnetic materials research unites the essential values of solid state physics and chemistry, of electronic and chemical manufacturing of materials science. Molecular interactions are also known as intermolecular interactions or noncovalent interactions which are not chemical reactions. The process of melting, unfolding, strand separation, boiling and disassembly involves changes in molecular interactions. The time dependence and rigid rotation are basic parameters of electronic and magnetic materials. Molecular dynamics is a type of N-body simulation. It is a computer simulation method to identify the physical movements of atoms and molecules allowed to interact for a given period of time to produce dynamic evolution of the system.   

Market Analysis

Materials Science 2018

Theme: Modernization of Materials Science and Nanotechnology

Summary:

Meetings International proudly announces the 2nd International Experts Meeting On Advances in Materials Science Research and Nanotechnology (Materials Science 2018) scheduled during October 29-30 2018 at Osaka, Japan. With a theme of “Modernization of Materials Science and Nanotechnology". The conference provides a Global Platform for Pharma, Biotech, Medical and Healthcare Professionals to Exchange Ideas, Knowledge and Networking at its 100+ International Conferences.

Materials are chain-like molecules made up of repeating chemical blocks and can be very long in length. Depending on the nature of the repeating unit they are made of polysaccharides, proteins of amino acids, and nucleic acids of nucleotides. The studies are more concerned to Green Composites, Biopolymer Feed Stock Challenges, Bio fibers & Microbial Cellulose, Biomaterials and Bio plastics. Advanced studies are being made to improvise developments in Biopolymer Technology, Waste Management, pharmaceutical and biomedical applications, Biodegrade ability, and many more.

For more details please visit: http://www.materialsmeetings.com/

Importance & Scope:

Over the past few years, global economic activities have increased a lot. This tremendous growth has raised serious problems about current important patterns of production and consumption. As the current society has increased its attention in understanding of the environmental aspects and its industrial practices, greater attention has been given to the concept of sustainable economic systems that rely on energy from undepletable source and materials. The use of biologically derived Polymers become as an important component of this global world.

Meetings International Materials Science Meeting will offer you an unmatched attendee experience. In addition to the many scientific sessions and take-home case study examples, you will leave this event with many other novel development strategies from some of our workshops and symposiums. Engage in dynamic conversation with your industry peers at our multiple networking sessions, and takeaway novel drug development and commercialization strategies, which could speed up time to market and save your organization millions. We hope you will join us in Osaka, Japan this October to enhance your drug delivery capabilities, and increase time to market on therapeutics.

Why Japan?

Japan is a world apart – a cultural Galápagos where a unique civilization blossomed, and today thrives in contrasts of traditional and modern. The Japanese spirit is strong, warm and incredibly welcoming. Japan is a leading nation in scientific research, particularly technology, machinery and biomedical research. Japan leads the world in robotics production and use.

Osaka is the second largest metropolitan area in Japan and serves a major economic hub. Historically a merchant city, Osaka has also been known as the “Nation’s Kitchen”. With a population of 2.5 million, Osaka is Japan's third largest and second most important city. It has been the economic powerhouse of the Kansai region for many centuries.

The city's west side has the main port as well as a tourist destination with attractions such as Kyocera Dome, Universal Studios Japan, Osaka aquarium, Minami, Osaka castle, Umeda sky building and the Tempozan Harbour Village. Osaka is known for its food, both in Japan and abroad. Author Michael Booth and food critic François Simon of Le Figaro have both suggested that Osaka is the food capital of the world. Osaka's culinary prevalence is the result of a location that has provided access to high quality ingredients, a high population of merchants, and close proximity to the ocean and waterway trade. In recent years, Osaka has started to garner more attention from foreigners with the increased popularity of cooking and dining in popular culture.

The National Museum of Art (NMAO) is a subterranean Japanese and international art museum, housing mainly collections from the post-war era and regularly welcoming temporary exhibitions. Osaka Science Museum is in a five storied building next to the National Museum of Art, with a planetarium and an OMNIMAX theatre. The Museum of Oriental Ceramics holds more than 2,000 pieces of ceramics, from China, Korea, Japan and Vietnam, featuring displays of some of their Korean celadon under natural light. The Osaka Museum of History, opened in 2001, is located in a 13-story modern building providing a view of Osaka Castle. Its exhibits cover the history of Osaka from pre-history to the present day. Osaka Museum of Natural History houses a collection related to natural history and life.

Why to attend?

Materials Science 2018 offers a fantastic opportunity to meet and make new contacts in the field of Bio materials, Polymer Science and engineering, by providing collaboration spaces and break-out rooms with tea and lunch for delegates between sessions with invaluable networking time for you. It allows delegates to have issues addressed on Bio materials by recognized global experts who are up to date with the latest developments in the Bio materials field and provide information on new techniques and technologies. This International Biopolymer and Polymer Chemistry and Materials conference will feature renowned keynote speakers, plenary speeches, young research forum, poster presentations, technical workshops and career guidance sessions.

Major Biopolymer Associations 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 Biomaterials Associations in Japan

  1. Society For Biomaterials
  2. Japan Society for Biomaterials
  3. Association for the Development of Biomaterials
  4. The Scandinavian Society for Biomaterials
  5. Federation Of Asian Materials Societies
  6. Federation of Asian Materials Society

Target Audience:

  • Eminent Scientists of Polymer Science & Chemical Engineering, Green Chemistry
  • Polymer Research Professors and research fellows
  • Students from Material science, Polymer Science and Technology & Chemical Engineering
  • Directors of Polymer Manufacturing companies, Green Chemicals Companies
  • Biopolymer Engineers, Polymer Science Engineers & Chemical Engineers
  • Members of different Biopolymer, Waste Management, Chemistry, Chemical Engineering associations

Industry40%
Academia 50%
Others 10%

Glance at Market of Biopolymers and Polymer Chemistry

               As there is need for eradication of polymers, there is increase in growth of industries for Biopolymers. Biopolymers have found wide acceptance in various industries, on account of its distinguished environment friendly properties. Biopolymers and Polymer Chemistry are now an important part of every sector Food tech, nanotech, chemistry, medical, agriculture etc.­

                 There is an increase of 20% (approx.) in the production of biopolymers products and Bioplastics per year. The biomaterials market is poised to reach USD 130.57 Billion by 2020, growing at a CAGR of 16% during the forecast period of 2015 to 2020. The biomaterials market is expected to witness the highest growth rate in the Asia-Pacific region, with emphasis on India, China, and Japan. The high growth in India and China can be attributed to rising cosmetic and plastic surgeries in India, lucrative medical device industry and new tax policy in China, growing number of cardiovascular diseases and increasing aging population in China.

Major Biopolymer Industries and their revenue (in millions) per year:

  • BASF
  • Dow Chemical
  • Sinopec
  • SABIC
  • Formosa Plastics
  • Ineos Group holdings
  • ExxonMobil
  • LyondellBassell industries
  • Mitsubishi Chemical
  • Dupont
  • LG chem
  • Nanotechnology in Materials Science
  • Bionanotechnology and Nanomedicine
  • Materials Science & Engineering
  • Materials in Industry
  • Materials for Energy and Applications
  • Materials Chemistry and Analysis
  • Materials for Green Technology
  • Nanotechnology in Polymers
  • Nanostructures and Nanofabrications
  • Nanotechnology for biological system
  • Polymeric materials and Nano Robotics
  • Nanotechnology in communications & Information Technology
  • Metallurgy and Materials Science
  • Biomaterials and Tissue Engineering
  • Advances in Materials Science
  • Nanoelectronic devices
  • Electronic and Magnetic Materials
  • Mechanical application of Nanotechnology