• Emerging areas of Materials Science
• Smart materials
• Solar energy materials & systems
• Advanced Graphene and Carbon Materials
• Light-weight energy-efficient structural materials

• 2-D materials beyond graphene
• Carbon Nanostructures and Grapheme
• Green Energy Materials
• Chemical and mechanical properties of graphene and 2-D materials
• Applications of graphene in various forms

• Biocompatible Polymers
• 3D Nanodtructured Materials
• Advanced engineering materials
• Smart Polymers
• Nanoassemblies

• Inorganic/Organic Nanomaterials
• Biosensors, Diagnostics and Imaging
• Nanocomposites
• Nanocrystalline materials
• Nanoporous material

• cellulose  nanowhiskers
• Cellulose Nano-Structures
• Nanofibers of Cellulose and Its Derivatives
• nanocellulose-based nanocomposites
• Bacterial nanocellulose

• Non-siliceous Inorganic Nanomaterials
• Nanostructured Catalysts
• Carbon Nano tubes
• Catalytic Applications of Nanoporous Materials
• Porous Polymers and Polymer/Inorganic Nanocomposites

• Modelling, simulation and control of smart materials
• Temperature-responsive polymers
• piezoelectric materials
• Shape-memory alloys
• Polymer-based smart materials

• Metal Matrix Composites
• Ceramic Matrix Composite
• Carbon Matrix Composite
• Polymer Matrix Composite
• Organic Matrix Composites

• Polymeric Biomaterials
• Metallic Biomaterials
• Classes of Nanostructured Biomaterials
• Biomedical Applications and Translational Aspects of Nanomaterials
• Biodegradable Polymeric Biomaterials

• Polymers in bulletproof vests and fire-resistant jackets
• Polymer nanocomposites matrices
• Polymers for Drug Delivery
• Block copolymer nanocomposites
• Polymers in Implants and Medical Devices

• Carbon Nanotube Field Effect Transister(CNFET)
• Nanostructured Multiphase Alloys
• Quantum Mechanics for Modelling of Nanomaterials
• Software for Modelling of Nanomaterials
• Industrial Applications of Nanomaterials Modelling

One of the most interesting things about nanotechnology is that the houses of many substances trade when the measurement scale of their dimensions techniques nanometers. Materials scientists work to understand these property changes and utilize them in the processing and manufacture of substances at the nanoscale. New methods to create Nanophase materials have arisen in the improvement of a new category of materials. For instance, a Nanophase cloth with an average grain size of 5nm has about 50% of the atoms inside the first two nearest neighbor planes of a grain boundary in which good sized displacements from normal lattice positions are displaced.

Materials Science and Engineering is the study of all materials, from those we see and use each day such as a glass or a piece of game tools to those used in aerospace and medicine, thru that understanding how materials work, can create new materials for new purposes as well as develop present substances to enhance performance. They can control the shape of a material, from an atomic level up.

• Dimensionality In Nano Materials
• Nanofabrication
• Nanomedicine
• Nano Platelet
• Nanophotonics

Nanotechnology is a promising science with large functions from cosmetics, food products, clothing, and family home equipment to gasoline catalyst, ailment treatment, and renewable energies. Nanotechnology is additionally being applied to a variety of industrial and purification methods such as development materials, nanomachining of nanowires, nanorods, graphene, water filtration, and wastewater treatment. Their functions are turning into wider in “nanomedicine” by using interfacing the nanomaterials with organic molecules or structures, “green technology” to beautify the environmental sustainability and “renewable energy” to advance the new approaches to capture, store, and transfer energy.

For instance, carbon nanotube productions have been used for purposes in energy storage, automotive parts, thin-film electronics, coatings, and so forth. Nanomaterials are located as necessary and hold growing in the area of Nanoscience and Nanotechnology and in latest years researchers are investing a good deal effort on the synthesis and applications of a number of nanomaterials, due to their viable functions in science and industry. For example, biocompatible nanomaterials are utilized without delay or they are used to exchange natural materials to function or to be in contact with the living systems.

• Synthesis and Processing of Emerging Two-Dimensional Nanomaterials
• Microwave-Assisted Synthesis for Carbon Nanomaterials
• Strategies in Laser-Induced Synthesis of Nanomaterials
• Recent Trends in the Synthesis of Carbon Nanomaterials
• Chemical Approaches for 1D Oxide Nanostructures

The primeval ceramics made by way of human beings have been pottery objects, which include 27,000-year-old figurines, made from clay, either thru itself or blended with distinctive materials like silica, hardened, sintered, in fire. Later ceramics had been glazed and fired to produce smooth, colored surfaces, decreasing porosity through the use of glassy, amorphous ceramic coatings on pinnacle of the crystalline ceramic substrates. Ceramics currently encompass domestic, industrial and developing products, as well as a wide fluctuate of ceramic art. In the twentieth century, new ceramic materials have been 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 embody polymer chemistry and polymer physics). Historically, merchandise bobbing up from the linkage of repeating devices via covalent chemical bonds have been the principal focal point of polymer science; rising essential areas of the science presently focal point on non-covalent links. Composite components are usually used for buildings, bridges and constructions like boat hulls, swimming pool panels, race automobile bodies, shower stalls, bathtubs, storage tanks, imitation granite and cultured marble sinks and counter tops. The most superior examples operate automatically on spacecraft in stressful environments. Now standing at USD 296.2 billion, the ceramics market is forecast to develop to USD 502.8 billion by using 2020, as every and each and every enterprise achieves upgraded manufacturing effectivity alongside with high renewable electricity efficiency. As per the international market analysis, in 2014, the Composite substances enterprise is predicted to generate income of about 156.12 billion U.S. dollars.

• Ceramic and composite construction materials
• Ceramics Coating
• Novel synthesis and processing of ceramics
• Fabrication methods of composites
• Bioceramics and medical applications

Nanotechnology has developed a sustainable energy manufacturing scheme which is one of the most necessary scientific challenges of the 21st century. The assignment is to design, to synthesize and to represent new functional nanomaterials with controllable sizes, shapes and/or structures.

It is now one of the quickest growing lookup fields in the world and will optimistically head to the improvement of a renewable strength economy in which fossil gasoline resources will solely be used to produce more valuable chemicals. This vision is that energy, environmental and safety troubles created with the aid of the consumption of fossil fuels will be solved as soon as and for all.

• Environmental health and safety
• Solar power technology and material
• Energy storage & Novel Generation
• Oil,gas,Nuclear & Traditional energy

Tissue engineering is very fast developing scientific area in this era and used to create, repair, and/or substitute cells, tissues and organs with the aid of the use of mobile phone and/or combinations of cells with biomaterials and/or biologically active molecules and helps to produce substances which very lots resembles to body's native tissue/tissues. Novel biomimetic scaffold” and “Modern technology” been developed for greater accuracy on positioning and viability, complexity, interplay etc., the usage of micro and nanotechnology for manufacturing and analytical control through tools.3 Micro and nanotechnology are offering them simple substrate for adhesion and proliferation and lively agents for their growth.

Nanofabrication techniques, substances science, surface, micro and nano-patterning in tissue engineering helps in offering fine microenvironment the place cells have to grow. Nanotechnology can be used to create nanofibers, nanopatterns and controlled-release nanoparticles with functions in tissue engineering, for mimicking native tissues considering the fact that biomaterials to be engineered is of nano metre size like extracellular fluids, bone marrow, cardiac tissues etc. The gain of nanoparticles in TE stems from their small dimension and their related large floor to extent ratio, which is related to peptides and small proteins. They can without difficulty diffuse throughout membranes and facilitate uptake by means of cells. Moreover, one is now not restricted by means of a predetermined measurement for nanoparticles, given that they can be made in customized sizes and floor traits in order to swimsuit any purpose. Nanoparticles also mimic the natural nanometer measurement scale of extracellular matrix (ECM) factors of tissues themselves.

• Nanotextured substrates for tissue engineering
• Self-assembled nanomaterials
• Biological property enhancement: increased cell proliferation rates
• Enhancement of mechanical properties
• Enhancement of electrical properties

Nanotechnology is widely applied in our every day life and is altering the complete society. It has begun marching into the agriculture and food enterprise on the grounds that 2003 when United States Department of Agriculture posted the first roadmap in September 9, 2003. Research on this subject matter has skyrocketed over the last decade. It nearly covers each and every thing in the meals and agriculture industry, together with agriculture, irrigation/water filtration, food processing and packaging, animal feed, and aquiculture.  The food and beverage sector is a international multi trillion dollar industry. A latest estimate of the world in your price range have an effect on of nanotechnology is projected to be at least $3 trillion by way of 2020, which may additionally worker 6 million labors in the rising nanotechnology industries worldwide.

This is very beautiful and has driven many meals firms concerned in development and marketing of novel nanomaterial based products, and improving production efficiency, meals characteristics, taste and safety. Incredibly, there are heaps of products that have already been marketed and used in the meals enterprise over the previous decade. Majority of these products are designed “out-of-food” but “inside” meals industry, i.e. food contacting substances however now not at once ate up by way of people. No novel nanomaterials containing merchandise have been without delay put into human meals yet, without titanium dioxide and iron oxide that have been used as meals pigment and colorant respectively already. The vital reason is that rules and regulation is very restricted involving nano food, particularly due to complexity of nanomaterials and case-by-case legislating strategies  A deeper reason for the limited regulation is the poor information of toxicity and risk which novel nanomaterials should bring. Many studies focal point on in vitro toxicity of nanomaterials whilst very little in vivo toxicity data is available, now not to mention chronic effect of nanomaterials (especially metallic nanoparticles, NPs). At least countless gaps have to be filled: toxicity of nanomaterial to mammal cells, tissues/organs and continual effect to human body; migration of nanomaterials to food; degradation or environmental destiny of nanomaterials; bioaccumulation of nanomaterials and their affect on ecosystems.

• Nanomaterials as Agents to Stimulate Plant Growth
• Nano-d for the Management of the Food Supply Chain
• Nano-delivery systems

Green materials are materials that are nearby and renewable. Local materials regularly are special to the area and join something humans make within a place or region. Materials from the floor such as clay, sand, and stone are green materials as they are observed underfoot. Plant substances such as grasses, straw, timber, and bamboo are also materials that have been used with the aid of people when you consider that they started out building. Plant substances that grow rapidly are for the most phase renewable. Reclaimed materials are substances that can be reused in their current structure for new purposes. Reclaimed substances are inexperienced in the experience that they can be re-purposed and reused.

Recyclable materials are materials that can move from being waste fabric to being reused through reprocessing or re-purposing. Green materials nowadays are described as substances that are non-toxic, improve occupancy health, decrease cost, and preserve electricity and water use and waste merchandise. Non-toxic materials are materials that do no longer reason damage to the environment, to the customers of the fabric or to the producers of the material. Green materials are additional materials that have low embedded strength in their harvesting or collection, production, transportation, and use. Material scientists work with chemical and biological engineers to develop new and higher materials. Let’s discover green materials