1:Materials Science and Metallurgy Materials Science also plays a major role in metallurgy. Powder metallurgy is a term that covers a wide range of ways of producing metal powder materials or components. We can eliminate the need to use metal extraction methods, or significantly reduce them, and can reduce costs. Thermal treatment for pyrometallurgy Minerals and metallurgical ores and concentrate to turn the materials physically and chemically in order to recover valuable metals. Full metallurgical expertise will help us remove metal in a more feasible manner and be able to use it to a wider range. The global market for metallurgy will grow modestly It is estimated that the demand will hit 5.4 billion pounds by 2017 (a cost of almost $26.5 billion).

2: Advanced MaterialsAdvanced  Materials, opened here as materials and their related methodology propellants, with the likelihood of being abused in highly superimposed stocks, are each multidisciplinary, such as physical science, science, associated mathematics and navigate every advancement area, such as normal science and photonics, biosciences and nearby market parts. Imperative, transport, social welfare, packaging. Advanced Materials is a peer-reviewed weekly scientific journal covering the study of materials. This provides correspondence, reviews, and features reports on chemistry, physics, nanotechnology, ceramics, metallurgy, and biomaterials subjects.

3: Nano TechnologyNano engineering is set out in view of the fact that science handles the tiny, intense particles or one measurement approximate particles from one to one hundred nm referred to as nanoparticles. These particles are capable of monitoring unique iotas and atoms. Because of the various potential applications, a wide range of tests goes under the nanotechnology throughout the world. Such as surface science, compound science, organic science, semiconductor material science, stockpiling of vitality, little creation, subatomic construction, and soon. Nano technology includes science, design, and innovation, and includes Nano-scale imagery, measurement, display, and control.

Session-4: Material Synthesis and CharacterizationThe development of materials with desired structure and properties requires the use of several completely different process phases. The fabric structure, property, and process (Materials Paradigm) should be legendary as a cloth investigator. The fabric cannot be manufactured in business and marketing unless it is cost-effective And it’s established a qualitative manufacturing methodology. The process of materials is therefore important to the materials science sector. The model of the subject aids in aviation accidents in rhetorical science, malfunction evaluation, and investigation. Recently, many sensitive materials have emerged or modified synthesis steps through new production methods.

Session-5: Optical, Magnetic and Electronic MaterialsResearch on optics, magnetic and electronic content combines the principles of many science fields such as solid state physics, chemistry, materials science, electronics, and chemistry. Magnetic materials will be used in research and data processing, super magnetism and spintronics. Industries of semi-conductors and energy. Their optical properties in various materials such as glass, ceramics, electrical, semiconductors, nanopromocytes and polymer fibers have been modified to meet the demands of the energy conservation, national security and commercial sector.

Session-6: NanotechnologyNanotechnology is evolving rapidly and merged with the Materials Science field. Intelligent materials at the nanotech level or the synthesis of nanomaterial’s may have different properties to find applications in the materials industry for healthcare, construction and materials. Receive electrical, nanometre / photonic and pseozoillectrical applications in the electronic, semiconductor and energy industries. Their optical properties have been modified in various materials such as glass, ceramics, electrics, semiconductors, nanopromocytes and polymer fibres to meet the demands of the energy conservation, national security and commercial sector.

Session-7: Piezoelectric Materials and 3-D PrintingPiezoelectric materials are smart materials that accumulate electrical load at mechanical stress throughout the material surface and this load can alter the material’s shape. Ceramic, quartz, quantum dots, etc. are some of these materials. Such digital materials are used in the automotive industry as sensors and actuators. Rapid prototyping, 3dimensional (3D) printing or additive manufacturing (AM) of smart materials such as smart nano composites, shape memory alloys, ceramics, shape memory polymers, soft robotics actuators, self-evolving structures, anti-counterfeiting systems, and 4D printing also included structural material reconfiguration over time.

Session-8: Materials in HealthcareExploring perfect restorative material for medicine gave hope in dental science for applications of sensitive materials. Sensitive materials are materials whose properties can be modified to support the structure of the tooth during a controlled fashion. Enamel and dentin will be imitated by susceptible biomimetic products. The place of work Sensitive materials such as sensitive composites, sensitive ceramics, resin-modified glass monomers, amorphous phosphate emotional pit and fissure sealants, memory alloys in dentistry, sensitive impression material, sensitive suture, smart burs, etc. have revolutionized medicine and maximized the advantage of standard restorative techniques. Sensitive materials found their applications together.

Session-9: Market Demand and FutureIn the coming years, the market for intelligent materials and structures is expected to exceed $40 billion and the market is segmented by products, end-user applications, and geography. In many universities, R&D funding, government support, science and security and the adoption of intelligent content Products have led to the smart goods market in many areas such as aerospace, automotive, healthcare and consumer electronics. There are many promises for these emerging materials in the future in many areas of applications like energy, architecture, textiles, ceramics, automotive, aerospace, equipment, medical and electronics industries.

Session-10: Ceramics and Textiles IndustriesCeramics were the earlier brittle materials in compression that were exhausting and robust and weak in tension and cutting. In order to improvise their properties, they incorporated good materials that diode semiconductor into good ceramics that unite ceramic materials fictional from ultrafine Particulate victimization of the sol-gel path, better ceramics perform applications in bone surgery, tissue engineering, dental applications, bio-imaging, sensors, paints and pigments, optics, natural philosophy, drug delivery and material supply.

Session-11: Polymer Science and EngineeringThe field of science that studies the synthesis and applications of chemical compound materials (polymers) is polymer science and engineering. The crystallization and polymerisation of polymers, chemical compound engineering technology, materials science and physics research and the use of chemical compounds in many Products such as lithium-ion polymer battery (LiPo), electro active polymers, chemical compound comb, self-assembled chemical compound films, Nano-sphere chemical elements, collagen, enzymes, elastin, cellulose, chitin, fabrics, fibres and adhesives. During this f, sensitive materials such as electrical materials, self-healing and memory polymers also returned underneath analyses.

Session-12: Sustainable Energy and DevelopmentNatural resource depletion and population growth around the world have created a worldwide demand for energy. Industries are hoping for renewable sources of energy, super capacitors, battery energy storage, thermoelectric systems, transfer of energy by star cells and fuel cells.  Would you like to grow for Production and processing of electricity, equipment as well as various components, processes and properties are used, for example, batteries such as atomic number 3 battery area units used in many types of mobile devices, as well as appliances, electronics, recreational vehicles, power tools, toys, games, lighting and medical devices. Semiconductor devices have replaced vacuum tubes and diodes, transistors, light-weight emitting diodes (LEDs) for energy efficiency have emerged from these semiconductor materials.