Track Categories

The track category is the heading under which your abstract will be reviewed and later published in the conference printed matters if accepted. During the submission process, you will be asked to select one track category for your abstract.

Mechanics of materials is a subject which manages the conduct of vigorous items subject to stresses and strains. The entire hypothesis commenced with the phrenic conception of the conduct of one and two dimensional individuals from structures, whose conditions of stress can be approximated as two dimensional, and was then summed up to three quantifications to build up a more total hypothesis of the multifarious and plastic conduct of materials. The investigation of quality of materials frequently alludes to different strategies for computing the anxieties and strains in auxiliary individuals, for example, bars, sections, and shafts. The techniques utilized to anticipate the reaction of a structure under stacking and its defenselessness to different disappointment modes considers the properties of the materials, for example, its yield quality, extreme quality, Adolescent's modulus, and Poisson's proportion; likewise the mechanical component's naturally visible properties (geometric properties, for example, its length, width, thickness, limit requisites and unexpected vicissitudes in geometry, for example, apertures are considered.


  • Track 1-1 Stress
  • Track 1-2 Strain
  • Track 1-3 Loading type

Material Physics is the utilization of physical science to portray the physical properties of materials. It is a mix of physical sciences, for example, strong mechanics, strong state physical science, and materials science. Materials physical science is viewed as a subset of dense issue material science and applies major consolidated issue ideas to complex multiphase media. They have a wide use in different fields which incorporates the advancement of Optoelectronic Materials and Devices and make utilization of quantum specks which are pervasive in semiconductors. A wide range of subjects constitutes material science which is Photo catalysis, laser material science, molecule material science and explanatory physical science. The market for printable or conceivably printable photovoltaic is relied upon to ascend from 260 million euros (2011) to approximately 5.7 billion euros by 2021. The worldwide market for semiconductor segment advertise came to $335.8 billion of every 2014, advance amid the determined period from 2015 to 2020; the market is relied upon to reach $593.6 billion by 2020 at a five year CAGR of 10.1%. The memory items keep on driving the general market other than the small scale parts, ICs, discrete and optical items. he rivalry in the worldwide semiconductor advertise is exceptional inside a couple of huge players, for example, AMD, Amkor, Broadcom, Cabot Microelectronics, Elpida, Fairchild, Free scale, Fujitsu, Global Foundries, Infineon, Intel, Marvell, Media Tek, Micron, NEC, NVIDIA, NXP, Qualcomm and so forth. Condensed matter physics


  • Track 2-1 Thin films
  • Track 2-2 Optoelectronics
  • Track 2-3 Photo catalysis
  • Track 2-4 Particle astrophysics
  • Track 2-5 Laser physics
  • Track 2-6 Atomics and molecular physics

Material science includes the blend and investigation of materials that have fascinating and possibly helpful electronic, attractive, optical, and mechanical properties. Material science is a standout amongst the most talked points over the most recent couple of years. They are the new branch of materials science which exploit new improvements in science. Truth be told, science may give a total new leading body of materials for materials researchers and architects to utilize. Science started, and to a great extent proceeds with today, to be inseparably connected with getting ready, handling, and using materials. A significant part of the concentration of materials science in finding and creating materials that might be abused for wanted applications. Today, numerous materials scientific experts are integrating practical gadget materials, and the teach is frequently observed as coordinated towards creating materials with work—electrical, optical, or attractive. Material science is associated with the outlining and handling of materials. Worldwide market for impetuses is relied upon to reach $28.5 billion by 2020, developing at a CAGR (2015 to 2020) of more than 3%. Asia-Pacific is having the biggest market for impetuses representing over 35% offer. Significant players for Catalysts are Albemarle, Arkema, BASF, Chevron, Clariant, Dupont, Zeolyst International and others. Sol-gel technique


  • Track 3-1 Structural analysis of materials
  • Track 3-2 Materials at high-pressure
  • Track 3-3 Chemical engineering
  • Track 3-4 Materials synthesis
  • Track 3-5 Catalysis techniques
  • Track 3-6 Spectroscopic techniques
  • Track 3-7 Diffusion in materials

Material science has a more extensive scope of utilizes which incorporates earthenware engenderment, composites and polymer materials. Holding in earthenware engenderment and glasses utilizes both covalent and ionic-covalent sorts with SiO2 as an essential building square. Earthenware engenderment are as delicate as mud or as hard as stone and cement. Generally, they are crystalline in shape. Most glasses contain a metal oxide melded with silica. Applications go from rudimental components, for example, steel-fortified cement, to the gorilla glass. Polymers are likewise a critical piece of materials science. Polymers are the crude materials which are utilized to make what we conventionally call plastics. Claim to fame plastics are materials with particular attributes, for example, ultra-high quality, electrical conductivity, electro-fluorescence, high warm solidness. Plastics are partitioned not on the premise of their material but rather on its properties and applications. The ecumenical market for carbon fiber came to $1.8 billion of every 2014, and further the market is relied upon to develop at a five-year CAGR (2015 to 2020) of 11.4%, to reach $3.5 billion out of 2020. Carbon fiber fortified plastic market came to $17.3 billion of every 2014, and further the market is required to develop at a five-year CAGR (2015 to 2020) of 12.3%, to reach $34.2 billion out of 2020. The opposition in the ecumenical carbon fiber and carbon fiber invigorated plastic market is extraordinary inside a couple of extensive players, for example, Toray Toho, Mitsubishi, Hexcel, Formosa, SGL carbon, Cytec, Aksa, Hyosung, Sabic, and so on.Process modelling and simulation.


  • Track 4-1 Neat polymeric materials
  • Track 4-2 Hybrid polymer-based materials
  • Track 4-3 Polymer blends and alloys
  • Track 4-4 Extrusion and extrusion processes
  • Track 4-5 Rheology and Rheometry
  • Track 4-6 Elastomers and thermoplastic elastomers
  • Track 4-7 Polymeric catalysts
  • Track 4-8 Polymeric biomaterials

Optical Materials used for the trading of light by infers that of shrewd, holding, focusing or part of an optical shaft. The result of those materials is incredibly poor of the distinctive wavelengths. A broad assortment of asks about were coordinated and prompts the change of lasers, warm surge, photon conductivity and optical strands et cetera.


  • Track 5-1 Photonic Crystals
  • Track 5-2 Holography
  • Track 5-3 Optical Sensors
  • Track 5-4 Opto-Acoustic Materials
  • Track 5-5 Optical Nano Structures

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.


Materials Science has a more broad extent of usages which joins ceramic generation, composites and polymer materials. Stoneware are as sensitive as earth or as hard as stone and bond. Generally, they are crystalline in outline. Most glasses contain a metal oxide merged with silica. Applications stretch out from assistant parts, for instance, steel-fortified bond, to the gorilla glass. Polymers are furthermore a basic bit of materials science. Polymers are the unrefined materials which are used to make what we as a rule call plastics. Plastics are isolated not founded on their material but instead on its properties and applications. The overall market for carbon fiber came to $1.8 billion out of 2014, and further the market is depended upon to create at a five-year CAGR (2015 to 2020) of 11.4%, to reach $3.5 billion of each 2020. Carbon fiber reinforced plastic market came to $17.3 billion out of 2014, and further the market is depended upon to create at a five-year CAGR (2015 to 2020) of 12.3%, to reach $34.2 billion out of 2020. The resistance in the overall carbon fiber and carbon fiber invigorated plastic market is outstanding inside several generous players, for instance, Toray Toho, Mitsubishi, Hexcel, Formosa, SGL carbon, Cytec, Aksa, Hyosung, Sabic, etc.



Composite materials are organized materials made out of at least two perceptible stages. Applications run from basic components, for example, steel-strengthened cement, to the warm protecting tiles which play a key and indispensable part in NASA's Space Shuttle warm insurance framework which is utilized to shield the surface of the bus from the warmth of reentry into the Earth's climate. One illustration is fortified Carbon-Carbon (RCC), the light dim material which withstands re-entry temperatures up to 1,510 °C (2,750 °F) and secures the Space Shuttle's wing driving edges and nose top. RCC is a covered composite material produced using graphite rayon fabric and impregnated with a phenolic pitch. Subsequent to curing at high temperature in an autoclave, the cover is pyrolized to change over the gum to carbon, impregnated with furfural liquor in a vacuum chamber, and cured-pyrolized to change over the furfuralalcohol to carbon. To give oxidation protection from reuse capacity, the external layers of the RCC are changed over to silicon carbide.


Devices Multifunctional energy storage and conversion devices that incorporate novel features and functions in intelligent and interactive modes, represent a radical advance in consumer products, such as wearable electronics, healthcare devices, artificial intelligence, electric vehicles, smart household, and space satellites, etc. Advisable materials, device designs, and performances are crucial for the development of energy electronics endowed with these smart functions. Integrating these smart functions in energy storage and conversion devices gives rise to great challenges from the viewpoint of both understanding the fundamental mechanisms and practical implementation.


For any electric gadget to work well, electrical current must be productively controlled by exchanging gadgets, which ends up plainly difficult as frameworks approach little measurements. This issue must be tended to by integrating materials that allow solid turn-on and kill of current at any size scale. New electronic and photonic nanomaterials guarantee sensational leaps forward in interchanges, registering gadgets and strong state lighting. Flow investigate includes mass gem development, natural semiconductors, thin film and nanostructure development, and delicate lithography. A few of the major photonics organizations on the planet sees on various advancements and suppositions about future difficulties for makers and integrators of lasers and photonics items. The silicon photonics advertise is foreseen to develop to $497.53 million by 2020, extending at a CAGR of 27.74% from 2014 to 2020. The silicon carbide semiconductors advertise is evaluated to develop $3182.89 Million by 2020, at a normal CAGR of 42.03% from 2014 to 2020.Film Dosimetry and Image Analysis


  • Track 10-1 Semiconductor materials
  • Track 10-2 Fabrication of integrated circuits
  • Track 10-3 Semiconductor devices
  • Track 10-4 Soft magnetic materials
  • Track 10-5 Hard magnetic materials
  • Track 10-6 Dielectric materials
  • Track 10-7 Electronic and ionic conduction
  • Track 10-8 Ferro electricity and piezoelectricity
  • Track 10-9 Superconductivity
  • Track 10-10 Magnetic Storage

By permitting numerous intensifies, some semiconductor materials are tuneable that outcomes in ternary, quaternary organizations. Uses of semiconductors materials are optoelectronic, sun oriented cells, Nano photonics, and quantum optics. Creation of cellulose Nano-structures by means of Nano Synthesis is an immediate change of TMSC layers into cellulose by means of a Nano-sized centered electron shaft as utilized as a part of examining electron magnifying lens. Types of semiconductor materials


  • Track 11-1 Fabrication
  • Track 11-2 Semiconductor alloy system
  • Track 11-3 Applications of Semiconductor materials

Nanotechnology will be utilized for Detection, Diagnostics, Therapeutics and Monitoring. Themes like Nanotechnology based Imaging Technologies and Lab-on-a-Chip Point of Care Diagnostics, Advanced Nano-Bio-Sensor Technologies, Implantable Nano sensors, Nano Arrays for Advanced Diagnostics and Therapy, Invasive Therapy Technologies and Cellular based Therapy might be talked about.


  • Track 12-1 Nanotechnology and nanosensors
  • Track 12-2 Nanoparticles, nanodrugs and Nanomaterials
  • Track 12-3 Nanobiotechnology and Nanobiopharmaceutics
  • Track 12-4 Quantum Nanoscience
  • Track 12-5 Bionanoscience
  • Track 12-6 Nanobiopharmaceutics and Nanobiotechnology
  • Track 12-7 Toxicity and environmental impact of Nanoscale Materials

Diverse geophysical and social weights are giving a move from customary petroleum products to inexhaustible and supportable vitality sources. We should make the materials that will bolster rising vitality advancements. Sun based vitality is the best need of the office, and we are giving broad assets to creating photovoltaic cells that are both more effective and less expensive than current innovation. We likewise have broad research on cutting-edge battery innovation. Materials execution lies at the core of the advancement and enhancement of efficient power vitality innovations and computational techniques now assumes a noteworthy part in demonstrating and anticipating the properties of complex materials.


  • Track 13-1 Solid electrolytes and characterization
  • Track 13-2 Battery technologies
  • Track 13-3 Economics of materials
  • Track 13-4 Fuel cells
  • Track 13-5 Nuclear -waste management and disposal
  • Track 13-6 Solar fuels
  • Track 13-7 Geothermal and ocean Energy
  • Track 13-8 Related Conference of Materials for Green Technology

Holding in ceramic production and glasses utilizes covalent and ionic-covalent sorts with SiO2 (silica or sand) as a major building square. Pottery are as delicate as earth or as hard as stone and cement. For the most part, they are crystalline in frame. Building earthenware production are known for their firmness and solidness under high temperatures, pressure and electrical anxiety. Alumina, silicon carbide, and tungsten carbide are produced using a fine powder of their constituents in a procedure of sintering with a cover. Hot squeezing gives higher thickness material. Synthetic vapor testimony can put a film of an earthenware on another material. Ceramets are artistic particles containing a few metals.


Nanostructured materials might be characterized as those materials whose basic components—bunches, crystallites or particles—have measurements in the 1 to 100 nm go. The blast in both scholarly and modern enthusiasm for these materials over the previous decade emerges from the wonderful varieties in key electrical, optical and attractive properties that happen as one advances from a 'vastly expanded' strong to a molecule of material comprising of a countable number of particles. this survey subtle elements late advances in the blend and examination of practical nanostructured materials, concentrating on the novel size-subordinate physical science and science that outcomes when electrons are limited to nanoscale semiconductor and metal bunches and colloids. Carbon-based nanomaterials and nanostructures including fullerenes and nanotubes assume an undeniably inescapable part in nanoscale science and innovation and are in this way depicted in some profundity. Current nanodevice manufacture strategies and the future prospects for nanostructured materials and nanodevices.


  • Track 15-1 Nanofabrics
  • Track 15-2 Nanofiber
  • Track 15-3 Nanofoam
  • Track 15-4 Nanohole

Graphenated Carbon Nanotubes are a new half-breed that joins graphitic foliates developed with sidewalls of bamboo style CNTs. It has a high surface area with a 3D system of CNTs combined with the high edge thickness of Graphene. Concoction alteration of carbon nanotubes are covalent and non-covalent adjustments because of their hydrophobic nature and enhance bond to a mass polymer through a compound connection. Uses of the carbon nanotubes are composite fiber, wrenches, homerun sticks, Microscope tests, tissue building, vitality stockpiling, supercapacitor and so forth. Nanotubes are classified as single-walled and multi-walled nanotubes with related structures.


Nanotechnology in material science offers a solid prologue to principal ideas on the wellspring of material science. It conveys the focal issues of material science and incorporates imaginative research on Atomic and Nano structures and furthermore small scale and large scale structures. The essentials of material science likewise manage the Crystallography, holding properties, material union and with thermodynamic and active properties.


  • Track 17-1 Biomaterials
  • Track 17-2 Nanoparticle Targeting
  • Track 17-3 Nanomaterials
  • Track 17-4 Nanosensors

The medieval ages where stone, bronze, steel was utilized have now prompted development of Ceramics, Minerals from where Metallurgyfield stirred. Material science, Chemistry, thermodynamics and a few different fields of science have looked into metals, composites, silica and carbon nanomaterial.

Material Science has now reformed from metals and composites to semiconductors, plastics, biomaterials, rubbers, polymers, attractive materials, restorative embed materials, nanomaterial and so forth and it doesn't stop there yet! Shrewd structures are gadgets made out of keen materials fit for detecting upgrades, reacting to it and returning to its unique state after the boosts is expelled. Self-Healing Materials, Magnetocaloric and thermoelectric materials, Polycaprolactone are rising brilliant structures. Brilliant structures can oppose common catastrophes.A few materials like LiTraCon,Silicene, Aerogels, Graphene, Fullerene, Metamaterials, Quantum Dots and Lithium Ion Batteries have been developing. These developing savvy materials have discovered potential applications in wellbeing, aviation, car industry and so forth.


  • Track 18-1 Magneto caloric and thermoelectric materials
  • Track 18-2 Self-Healing materials
  • Track 18-3 Photomechanical materials
  • Track 18-4 Chemochromic and electrochromic materials
  • Track 18-5 Conductive Polymers
  • Track 18-6 Aerogels and Quantum Dots
  • Track 18-7 Graphene and Carbon Nanotubes
  • Track 18-8 Fullerene and Metamaterials

Materials portrayal is the wide and general process by which a material's structure and properties are examined and measured. It is an essential procedure in the field of materials science, without which no logical comprehension of building materials could be found out. While numerous portrayal systems have been rehearsed for a considerable length of time, for example, essential optical microscopy, new procedures and strategies are continually rising. Specifically the coming of the electron magnifying instrument and Secondary particle mass spectrometry in the twentieth century has reformed the field, permitting the imaging and investigation of structures and pieces on substantially littler scales than was beforehand conceivable, prompting a tremendous increment in the level of understanding with reference to why diverse materials indicate distinctive properties and practices. All the more as of late, nuclear power microscopy has additionally expanded the most extreme conceivable determination for investigation of specific specimens over the most recent 30 years