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20th World Congress on Materials Science and Engineering, will be organized around the theme “Exchange of Technological Advances in the field of Materials”

Materials Congress 2019 is comprised of 13 tracks and 209 sessions designed to offer comprehensive sessions that address current issues in Materials Congress 2019.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

Register now for the conference by choosing an appropriate package suitable to you.

Materials Science and Engineering is an acclaimed scientific discipline, expanding in recent decades to surround polymers, ceramics, glass, composite materials and biomaterials. Materials science and engineering, involves the discovery and design of new materials.  Many of the most pressing scientific problems humans currently face are due to the limitations of the materials that are available and, as a result, major breakthroughs in materials science are likely to affect the future of technology significantly. Materials scientists lay stress on understanding how the history of a material influences its structure, and thus its properties and performance. All engineered products from airplanes to musical instruments, alternative energy sources related to ecologically-friendly manufacturing processes, medical devices to artificial tissues, computer chips to data storage devices and many more are made from materials.  In fact, all new and altered materials are often at the heart of product innovation in highly diverse applications. The global market is projected to reach $6,000 million by 2020 and lodge a CAGR of 10.2% between 2015 and 2020 in terms of worth. The North American region remains the largest market, accompanied by Asia-Pacific. The Europe market is estimated to be growth at a steady rate due to economic redeem in the region along with the expanding concern for the building insulation and energy savings.

  • Track 1-1Teaching and technology transfer in materials science
  • Track 1-2Electromagnetic radiation
  • Track 1-3Polymeric biomaterials
  • Track 1-4Scientific and business achivements
  • Track 1-5Fiber, films and membranes
  • Track 1-6Biomimetic materials
  • Track 1-7Coatings, surfaces snd membranes
  • Track 1-8Carbon nano structures and devices
  • Track 1-9Graphene
  • Track 1-10Products and services
  • Track 1-11Computational materials science
  • Track 1-12Global materials science market
  • Track 1-13Modern materials need
  • Track 1-14Research support
  • Track 1-15Platform for comprehensive projects
  • Track 1-16Emerging materials and applications
  • Track 1-17Tribology
  • Track 1-18Forensic engineering
  • Track 1-19Engineering apllications of materials

Nanotechnology is the handling of matter on an atomic, molecular, and supramolecular scale.  The interesting aspect about nanotechnology is that the properties of many materials alter when the size scale of their dimensions approaches nanometers. Materials scientists and engineers work to understand those property changes and utilize them in the processing and manufacture of materials at the nanoscale level. The field of materials science covers the discovery, characterization, properties, and use of nanoscale materials. Nanomaterials research takes a materials science-based approach to nanotechnology, influencing advances in materials metrology and synthesis which have been developed in support of microfabrication research. Materials with structure at the nanoscale level o have unique optical, electronic, or mechanical properties. Although much of nanotechnology's potential still remains un-utilized, investment in the field is booming. The U.S. government distributed more than a billion dollars to nanotechnology research in 2005 to find new developments in nanotechnology. China, Japan and the European Union have spent similar amounts. The hopes are the same on all fronts: to push oneself off a surface on a growing global market that the National Science Foundation estimates will be worth a trillion dollars. The global market for activated carbon totaled $1.9 billion, in 2013, driven primarily by Asia-Pacific and North American region for applications in water treatment and air purification.

  • Track 2-1Medical nanotechnology
  • Track 2-2Nanostructured Materials
  • Track 2-3Inorganic Analogues to Graphene
  • Track 2-4Nano/Meso-Structured Carbon Materials
  • Track 2-5Nano-Alloys
  • Track 2-6Nanotechnology startups
  • Track 2-7Environmental health and safety of nanomaterials
  • Track 2-8Micro, nano and bio fluidics
  • Track 2-9Nano and microfibrillated cellulose
  • Track 2-10Cancer nanotechnology
  • Track 2-11Nanobiotechnology
  • Track 2-12Nanophotonics
  • Track 2-13Nanoelectronics
  • Track 2-14Coatings, surfaces snd membranes
  • Track 2-15Carbon nano structures and devices
  • Track 2-16Nanofibers, nanorods, nanopowders and nanobelts
  • Track 2-17Thin Films, nanotubes and nanowires
  • Track 2-18Graphene
  • Track 2-19Synthesis of nanomaterials and properties
  • Track 2-20Nano and Biomaterials

Biomaterials from healthcare viewpoint can be defined as materials those possess some novel properties that makes them appropriate to come in immediate association with the living tissue without eliciting any adverse immune rejection reactions. Biomaterials are in the service of mankind through ancient times but subsequent evolution has made them more versatile and has increased their usage. Biomaterials have transformed the areas like bioengineering and tissue engineering for the development of strategies to counter life threatening diseases.  These concepts and technologies are being used for the treatment of different diseases like cardiac failure, fractures, deep skin injuries, etc.  Research is being performed to improve the existing methods and for the innovation of new approaches. With the current progress in biomaterials we can expect a future healthcare which will be economically feasible to us. Equipment and consumables was worth US$ 47.7 billion in 2014 and is further expected to reach US$ 55.5 billion in 2020 with a CAGR (2015 to 2020) of 3%. The dental equipment is the fastest growing market due to continuous technological innovations. The overall market is driven by increasing demand for professional dental services and growing consumer awareness. The major players in the Global Dental market are 3M ESPE, Danaher Corporation, Biolase Inc., Carestream Health Inc., GC Corporation, Straumann, Patterson Companies Inc., Sirona Dental Systems Inc., Planmeca Oy, DENTSPLY International Inc. A-Dec Inc.

  • Track 3-1Biopolymers and bioplastics
  • Track 3-2Biomimetic materials
  • Track 3-33D printing of organs and tissue
  • Track 3-4Biomedical devices
  • Track 3-5Bioinspired materials
  • Track 3-6Drug delivery systems
  • Track 3-7Tissue engineering and regenerative medicine
  • Track 3-8Biomaterials imaging
  • Track 3-9Drug delivery systems
  • Track 3-10Biomedical Applications of Nanoparticles
  • Track 3-11Friction, wear and fatigue in biomaterials
  • Track 3-12Hard and soft tissues
  • Track 3-13Surfaces and interfaces of biomaterials
  • Track 3-14Body implants and prosthesis
  • Track 3-15Radiotherapy
  • Track 3-16Soft and Biological Matter
  • Track 3-17Biomaterials for Tissue Regeneration

Different geophysical and social pressures are providing a shift from conventional fossil fuels to renewable and sustainable energy sources. We must create the materials that will support emergent energy technologiesSolar energy is a top priority of the department, and we are devoting extensive resources to developing photovoltaic cells that are both more efficient and less costly than current technology. We also have extensive research around next-generation battery technology. Materials performance lies at the heart of the development and optimization of green energy technologies and computational methods now plays a major role in modeling and predicting the properties of complex materials. The global market for supercapacitor is expected to grow from $1.8 billion in 2014 to $2.0 billion in 2015 at a year-on-year (YOY) growth rate of 9.2%. In addition, the market is expected to grow at a five-year CAGR (2015 to 2020) of 19.1%, to reach $4.8 billion in 2020. The competition in the global super capacitor market is intense within a few large players, such as, AVX Corp., Axion Power International, Inc., Beijing HCC Energy Tech. Co., Ltd., CAP-XX, Elna Co. Ltd., Elton, Graphene Laboratories INC., Jianghai Capacitor Co., Ltd, Jiangsu Shuangdeng Group Co., Ltd., Jinzhou Kaimei Power Co., Ltd, KEMET, LS MTRON, Maxwell Technologies INC., Nesscap Energy Inc., Nippon Chemi-Con Corp., Panasonic Co., Ltd., Shanghai Aowei Technology Development Co., Ltd., Skeleton Technologies, Supreme Power Systems Co., Ltd., XG Sciences.

  • Track 4-1Materials for Hydrogen Production, Storage and Fuel Cells
  • Track 4-2Advances on Biofuels—Materials, Characterization, Processing and Testing
  • Track 4-3Materials and Technologies for Energy Conversion, Saving and Storage (MATECSS)
  • Track 4-4Hybrid Materials for Energy Storage and Conversion
  • Track 4-5Advanced Polymer Photochemistry—From Fundamental Science to Material Technology
  • Track 4-6Photovoltaics, Solar Energy Materials and Technologies
  • Track 4-7Advances in Electrochemical Energy Storage

The primeval ceramics made by humans were pottery objects, including 27,000-year-old figurines, made from clay, either by itself or blended with other materials like silica, hardened, sintered, in fire. Later ceramics were glazed and fired to produce smooth, colored surfaces, decreasing porosity through the use of glassy, amorphous ceramic coatings on top of the crystalline ceramic substrates. Ceramics currently include domestic, industrial and building products, as well as a broad range of ceramic art. In the 20th century, new ceramic materials were developed for use in advanced ceramic engineering, such as in semiconductors. Polymers are investigated in the fields of biophysics and macromolecular science, and polymer science (which encompass polymer chemistry and polymer physics). Historically, products arising from the linkage of repeating units by covalent chemical bonds have been the primary focus of polymer science; emerging important areas of the science currently focus on non-covalent links. Composite materials are generally used for buildings, bridges and structures like boat hulls, swimming pool panels, race car bodies, shower stalls, bathtubs, storage tanks, imitation granite and cultured marble sinks and counter tops. The most advanced examples perform routinely on spacecraft in demanding environments. Now standing at USD 296.2 billion, the ceramics market is forecast to grow to USD 502.8 billion by 2020, as every industry achieves upgraded manufacturing efficiency along with high renewable energy efficiency. As per the global market analysis, in 2014, the Composite materials industry is expected to generate revenue of approximately 156.12 billion U.S. dollars.

  • Track 5-1Matrices & reinforcements for composites
  • Track 5-2Global environmental issues and standards
  • Track 5-3Structural analysis and applications
  • Track 5-4Measurement of material properties and structural performance
  • Track 5-5Glass science and technologies
  • Track 5-6Biocomposite materials
  • Track 5-7Composite materials in day-to-day life
  • Track 5-8Industrial applications of composite materials
  • Track 5-9Tribological performance of ceramics and composites
  • Track 5-10Fabrication of new composites based on light metals, polymers & ceramics
  • Track 5-11Processing, structure and properties of ceramics
  • Track 5-12Fabrication methods of composites
  • Track 5-13The future of the ceramics industry
  • Track 5-14Bioceramics and medical applications
  • Track 5-15Thermal ceramics
  • Track 5-16Nanostructured ceramics
  • Track 5-17Sintering process
  • Track 5-18Ceramic coatings
  • Track 5-19Performance in extreme environments
  • Track 5-20Advanced ceramics and glass for energy harvesting and storage

Material science has a wider range of applications which includes ceramics, composites and polymer materials. Bonding in ceramics and glasses uses both covalent and ionic-covalent types with SiO2 as a basic building block. Ceramics are as soft as clay or as hard as stone and concrete. Usually, they are crystalline in form. Most glasses contain a metal oxide fused with silica. Applications range from structural elements such as steel-reinforced concrete, to the gorilla glass. Polymers are also an important part of materials science. Polymers are the raw materials which are used to make what we commonly call plastics.  Specialty plastics are materials with distinctive characteristics, such as ultra-high strength, electrical conductivity, electro-fluorescence, high thermal stability. Plastics are divided not on the basis of their material but on its properties and applications. The global market for carbon fiber reached $1.8 billion in 2014, and further the market is expected to grow at a five-year CAGR (2015 to 2020) of 11.4%, to reach $3.5 billion in 2020. Carbon fiber reinforced plastic market reached $17.3 billion in 2014, and further the market is expected 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, Aksa, Hyosung, Sabic, etc.

  • Track 6-1Process modelling and simulation
  • Track 6-2Neat polymeric materials
  • Track 6-3Hybrid polymer-based materials
  • Track 6-4Polymer blends and alloys
  • Track 6-5Extrusion and extrusion processes
  • Track 6-6Rheology and rheometry
  • Track 6-7Elastomers and thermoplastic elastomers
  • Track 6-8Polymeric catalysts
  • Track 6-9Polymeric gels and networks
  • Track 6-10Polymer characterization
  • Track 6-11Polymer surface and interface
  • Track 6-12Polymer membranes for environments and energy
  • Track 6-13Engineering polymers
  • Track 6-14Fiber, films and membranes
  • Track 6-15Polymeric biomaterials

For any electronic device to operate well, electrical current must be efficiently controlled by switching devices, which becomes challenging as systems approach very small dimensions. This problem must be addressed by synthesizing materials that permit reliable turn-on and turn-off of current at any size scale. New electronic and photonic nanomaterials assure dramatic breakthroughs in communications, computing devices and solid-state lighting. Current research involves bulk crystal growth, organic semiconductors, thin film and nanostructure growth, and soft lithography. Several of the major photonics companies in the world views on different technologies and opinions about future challenges for manufacturers and integrators of lasers and photonics products. The silicon photonics market is anticipated to grow to $497.53 million by 2020, expanding at a CAGR of 27.74% from 2014 to 2020. The silicon carbide semiconductor market is estimated to grow $3182.89 Million by 2020, at an expected CAGR of 42.03% from 2014 to 2020.

  • Track 7-1Domains and hysteresis
  • Track 7-2Emerging Smart Materials
  • Track 7-3Photonic devices and applications
  • Track 7-4Spintronics
  • Track 7-5Quantum science and technology
  • Track 7-6Optical devices
  • Track 7-7Lasers
  • Track 7-8Optical communications and networking
  • Track 7-9Photoconductivity
  • Track 7-10Optical properties of metals and non-metals
  • Track 7-11Electromagnetic radiation
  • Track 7-12Film Dosimetry and Image Analysis
  • Track 7-13Magnetic Storage
  • Track 7-14Superconductivity
  • Track 7-15Ferroelectricity and piezoelectricity
  • Track 7-16Electronic and ionic conduction
  • Track 7-17Dieletric materials
  • Track 7-18Hard magnetic materials
  • Track 7-19Soft magnetic materials
  • Track 7-20Semiconductor devices
  • Track 7-21Fabrication of intigrated circuits
  • Track 7-22Semiconductor materials

Ability of a nation to harness nature as well as its ability to cope up with the challenges posed by it is determined by its complete knowledge of materials and its ability to develop and produce them for various applications. Advanced Materials are at the heart of many technological developments that touch our lives. Electronic materials for communication and information technology, optical fibers, laser fibers sensors for intelligent environment, energy materials for renewable energy and environment, light alloys for better transportation, materials for strategic applications and more. Advance materials have a wider role to play in the upcoming future years because of its multiple uses and can be of a greater help for whole humanity. The global market for conformal coating on electronics market the market is expected to grow at a CAGR of 7% from 2015 to 2020. The global market for polyurethanes has been growing at a CAGR (2016-2021) of 6.9%, driven by various application industries, such as, automotive; bedding and furniture; building and construction; packaging; electronics and footwear. In 2015, Asia-Pacific dominated the global polyurethanes market, followed by Europe and North America. BASF, Bayer, Dow Chemical, Mitsui Chemicals, Nippon Polyurethanes, Trelleborg, Woodbridge are some of the major manufacturers of polyurethanes across regions.

  • Track 8-1Smart robots
  • Track 8-2Electrochromic materials
  • Track 8-3Novel nano and micro-devices
  • Track 8-4Design and theory of smart surfaces
  • Track 8-5MEMS and NEMS devices and applications
  • Track 8-6Sensing and actuation
  • Track 8-7Structural health monitoring
  • Track 8-8Smart biomaterials
  • Track 8-9Smart building materials and structures
  • Track 8-10Architecture and cultural heritage
  • Track 8-11Development and characterization of multifunctional materials
  • Track 8-12Smart materials in drug delivery systems
  • Track 8-13Sensors and smart structures technologies for Civil, Mechanical, and Aerospace systems
  • Track 8-14Thin films and thick films
  • Track 8-15Quantum dots
  • Track 8-16Semiconductors and superconductors
  • Track 8-17Piezoelectric materials
  • Track 8-18Photovoltaics, fuel cells and solar cells
  • Track 8-19Energy storage device

Materials Chemistry provides the loop between atomic, molecular and supermolecular behaviour and the useful properties of a material. It lies at the core of numerous chemical-using industries. This deals with the atomic nuclei of the materials, and how they are arranged to provide molecules, crystals, etc. Much of properties of electrical, magnetic particles and chemical materials evolve from this level of structure. The length scales involved are in angstroms. The way in which the atoms and molecules are bonded and organized is fundamental to studying the properties and behaviour of any material. The forecast for R&D growth in the chemical and advanced materials industry indicates the improving global economy and the key markets the industry serves. U.S. R&D splurging in chemicals and advanced materials is forecast to grow by 3.6% to reach $12 billion in 2014. Overall global R&D is forecast to expand at a slightly higher 4.7% rate to $45 billion in 2014.

  • Track 9-1Solid state physics
  • Track 9-2Corrosion and degradation of materials
  • Track 9-3Phase diagrams
  • Track 9-4Atomic structure and interatomic bonding
  • Track 9-5Micro and macro molecules
  • Track 9-6Organic and inorganic Substances
  • Track 9-7Analytical chemistry
  • Track 9-8Dislocations and strengthening mechanisms
  • Track 9-9Diffusion in materials
  • Track 9-10Nanoscale physics
  • Track 9-11Particle physics
  • Track 9-12Corrosion prevention
  • Track 9-13Crystal structure of materials and crystal growth techniques
  • Track 9-14Quantum science and technology
  • Track 9-15Atomic structures and defects in materials
  • Track 9-16Magnetism and superconductivity
  • Track 9-17Multifunctional materials and structures
  • Track 9-18Condensed matter physics
  • Track 9-19Catalysis chemistry
  • Track 9-20Green chemistry
  • Track 9-21Solar physics
  • Track 9-22Oxidation

Material science plays a important role in metallurgy too. Powder metallurgy is a term covering a wide range of ways in which materials or components are made from metal powders. They can avoid, or greatly reduce, the need to use metal removal processes and can reduce the costs. Pyro metallurgy includes thermal treatment of minerals and metallurgical ores and concentrates to bring about physical and chemical transformations in the materials to enable recovery of valuable metals. A complete knowledge of metallurgy can help us to extract the metal in a more feasible way and can used to a wider range. Global Metallurgy market will develop at a modest 5.4% CAGR from 2014 to 2020. This will result in an increase in the market’s valuation from US$6 bn in 2013 to US$8.7 bn by 2020.  The global market for powder metallurgy parts and powder shipments was 4.3 billion pounds (valued at $20.7 billion) in 2011 and grew to nearly 4.5 billion pounds ($20.5 billion) in 2012. This market is expected to reach 5.4 billion pounds (a value of nearly $26.5 billion) by 2017.

  • Track 10-1Modeling and simulation
  • Track 10-2Environmental protection
  • Track 10-3Remelting technologies
  • Track 10-4Iron-Carbon alloys
  • Track 10-5Aluminium, Copper, Lead and Zinc
  • Track 10-6Light metals
  • Track 10-7Solidification
  • Track 10-8Surface phenomena
  • Track 10-9High strength alloys
  • Track 10-10Corrosion and protection
  • Track 10-11Non-destructive testing
  • Track 10-12Metal forming
  • Track 10-13Foundry technology
  • Track 10-14Precious metals
  • Track 10-15Gasification
  • Track 10-16Petroleum machinery and equipment
  • Track 10-17Hydrometallurgy
  • Track 10-18Metallurgical machinery and automation
  • Track 10-19Powder metallurgy
  • Track 10-20Alloys systems
  • Track 10-21Ferrous and non-ferrous metals
  • Track 10-22Iron, cast iron and steelmaking

Characterization, when used in materials science, refers to the broader and wider process by which a material's structure and properties are checked and measured. It is a fundamental process in the field of materials science, without which no scientific understanding of engineering materials could be as curtained. Spectroscopy refers to the measurement of radiation intensity as a function of wavelength. Microscopy is the technical field of using microscopes to view objects that cannot be seen with the naked eye.   Characterization and testing of materials is very important before the usage of materials. Proper testing of material can make the material more flexible and durable. Research indicates the global material testing equipment market generated revenues of $510.8 million in 2011, growing at a marginal rate of 3.1% over the previous year. The market is dominated by the ‘big three’ Tier 1 competitors, namely MTS Systems Corporation, Instron Corporation, and Zwick/Roell, while other participants have performed better regionally, such as Tinus Olsen in North America and Shimadzu Corporation in Asia Pacific.

  • Track 11-1Computational models and experiments
  • Track 11-2Atomic force microscopy (AFM)
  • Track 11-3Sample preparation and nanofabrication
  • Track 11-4Sample preparation and analysis of biological materials
  • Track 11-5Auger electron spectroscopy
  • Track 11-6Rutherford backscattering
  • Track 11-7Secondary ion mass spectrometry (SIMS)
  • Track 11-8X-ray photoelectron spectroscopy (XPS)
  • Track 11-9X-ray diffraction (XRD)
  • Track 11-10Optical spectroscopy (Raman, FTIR, ellipsometry, etc.
  • Track 11-11Scanning and transmission electron microscopy (SEM, TEM, STEM)
  • Track 11-12Mechanics of materials
  • Track 11-13Micro and macro materials characterisation
  • Track 11-14Structural analysis
  • Track 11-15Organic analysis
  • Track 11-16Elemental analysis
  • Track 11-17Advanced modelling techniques
  • Track 11-18Contact, friction and mechanics of discrete systems
  • Track 11-19Coupled mechanics and biomaterials
  • Track 11-20Failure of quasi-brittle materials
  • Track 11-21Fatigue, reliability and lifetime predictions
  • Track 11-22Ductile damage and fracture

Graphene was the first 2D material to be isolated. Graphene and other two-dimensional materials have a long list of unique properties that have made it a hot topic for intense scientific research and the development of technological applications. These also have huge potential in their own right or in combination with Graphene. The extraordinary physical properties of Graphene and other 2D materials have the potential to both enhance existing technologies and also create a range of new applications. Pure Graphene has an exceptionally wide range of mechanical, thermal and electrical properties. Graphene can also greatly improve the thermal conductivity of a material improving heat dissipation. In applications which require very high electrical conductivity Graphene can either be used by itself or as an additive to other materials. Even in very low concentrations Graphene can greatly enhance the ability of electrical charge to flow in a material. Graphene’s ability to store electrical energy at very high densities is exceptional. This attribute, added to its ability to rapidly charge and discharge, makes it suitable for energy storage applications.

  • Track 12-1Benefits of 2D Materials
  • Track 12-22D materials beyond Graphene
  • Track 12-32D Topological Materials
  • Track 12-4Chemical functionalization of Graphene