Track 1: Material Science and Engineering:

Materials Science and Engineering (MSE) combines engineering, physics and chemistry principles to unravel real-world problems associated with nanotechnology, energy, manufacturing biotechnology, information technology and other major engineering disciplines. Material Science and Engineering is that the field that leads within the discovery and development of the things that creates everything work. Materials science is additionally an important a neighborhood of forensic engineering and failure analysis investigating materials, products, structures or components, which fail or don't function as intended, causing personal injury or damage to property.

• Materials Synthesis

• Quantum Materials

• Novel Materials, Multifunctional Materials

• Transistor gate materials

• Photovoltaic

• Magnetic Materials

• Fracture analysis

Track 2: Nanomaterials and Nanotechnology:

Nanotechnology may be a relatively new branch of science that has found a good range of applications that range from energy production to industrial production that processes to biomedical applications. Materials scientists and engineers work to know those property changes and utilize them within the processing and manufacture of materials at the nanoscale level. Nanomaterials (NMs) are often engineered to possess unique composition and functionalities, which may provide novel tools and techniques. Nanotechnology (NT) is proposed presently to define because the complex of fundamental and engineering sciences that integrates a chemistry, physics and biology of nanostructures with a materials science, electronics, and processes technologies focused on a comprehensive research of nanostructures, on a development of atomistic physical chemical processes, self- and automatic-assembling of nanomaterial’s and work pieces using complex probe microscopes combined with other tools, resulted in a fabrication and manufacturing of Nano devices, Nano machines etc.

• Nanobiotechnology

• Nanotechnology for Energy and the Environment

• Risks and Regulation of Nanotechnology

• Nanocharacterization & Nanomanufacturing

Track 3: Biomaterials and Medical Devices:

Biomaterials are defined, as any synthetic material that's wont to replace or restore function to a body tissue and is continuously or intermittently in touch with body fluids. By concerning the manufacturing of medical devices, the event of latest biomaterials, new manufacturing methods and techniques have always been on researchers focus. One of the first reasons that biomaterials are used is to physically replace hard or soft tissues that became damaged or destroyed through some pathologic process .A biomaterial is distinguished by its biocompatibility, which means the ability of a material to promote its adequate response from the host in a specific situation.

Track 4: Bionanotechnology:

Bionanotechnology may be a science that sits at the convergence of nanotechnology and biology. Nano biotechnology is employed in reference to the ways during which nanotechnology is employed to make materials, devices and systems for studying biological systems and developing new diagnostic, therapeutic, biological assay, information storage and computing systems, among others. These systems use nanotechnology to advance the goals of biological fields. Bionanotechnology has created novel technologies for interfacing between nanoscale materials and biological systems supported investigating their interactions. Bionanotechnology has created new opportunities for advances in diverse fields, including electronics, engineering, and biotechnology, bioscience, and medicine.

Track 5: Opto-electronics:

Opto-electronics is that the study and application of electronic devices and systems that source detect and control light, usually considered a sub-field of photonics. Optical communications spawned sort of developments in optoelectronics, leading to devices like vertical-cavity surface-emitting lasers, semiconductor optical amplifiers, optical modulators, and avalanche photodiodes. At present, organic materials have received considerable attention because of their application in electronic and optoelectronic devices like organic thin film transistors, light emitting diodes (OLEDs), solar cells, and flexible printed electronics and so on.

Track 6: Materials for Green Technology:

Green tech–or green technology–is an umbrella term that describes the use of technology and science to create products that are more environmentally friendly. Green technologies are utilized in the recycling of wastewater, generation of power through solar panels, wind turbines, and such other industries. Green Technology may be a non-profit initiative designed to tell government efforts toward sustainability, providing a forum during which officialdom can communicate with those within the private sector who are developing and distributing green technologies.

Track 7: Nanomaterials:

Nanomaterials describe, in theory, materials of which one unit small sized between 1 and 100 nm. Materials engineered to such a little scale are often mentioned as engineered nanomaterials (ENMs), which can combat unique optical, magnetic, electrical, and other properties. The properties of nanomaterials aren't always well-characterized, and that they involve risk assessment of possible exposures arising during their manufacture and use. Nanoparticles can also be in touch with solids and liquids, especially in consumer products.

Track 8: Polymers Science & Nano Engineering:

Material science has a wider range of purposes which includes ceramics, composites and polymer materials. Bonding in ceramics and glasses uses each covalent and ionic-covalent kind with SiO2 as a simple building block. These polymers are specially made from carbon atoms bonded together into long chains that are termed because they are the backbone of the polymer. Polymer-based nanomaterials have great potential for the development of novel vaccines and drug systems for certain needs, including single-dose and needle-free deliveries of vaccine antigens and drugs in the future.

Track 9: Electrical, Optical, and Magnetic Materials:

Materials which may be magnetized and interested in a magnet are termed as ferromagnetic materials. Magnetic Smart Materials even have medical applications and it's predictable that they're going to increase within the future. Magnetic Smart Materials even have medical applications and it's predictable that they're going to increase within the future. Now-a-days Scientists also are occupied on the advancement of synthetic magnetic particles which may be inoculated into the physical body for the diagnosis and treatment of disease. Spintronic, also referred to as spin electronics or Flextronics, is that the study of the intrinsic spin of the electron and its related moment of a magnet , additionally to its vital electronic charge, in solid-state devices.

Track 10: Catalysis Materials:

Catalysis is that the process of accelerating the speed of a reaction by adding a substance is referred to as a catalyst. Importance of the compositional and morphological development of the catalyst requires understanding at the atomic level magnetic interaction between molecules of hydrogen and magnetically tailored open surface of the catalyst. The cost of producing these supplies on a marketable scale presents a serious challenge, which we've pursued to beat via the usage of gas as a source of carbon. Catalysts are divided in to 2 types homogeneous and heterogeneous. The heterogeneous catalysts are solids that are supplemented in to gas or liquid reaction mixtures, whereas the substance that's constant in composition is termed as homogenous mixture.

Track 11: Nanoengineering and its Applications:

Nanoengineering may be a branch of engineering that deals with all aspects of the planning , building, and use of engines, machines, and structures on the nanoscale. Correspondingly, but at the scale of atoms and molecules, nanoengineeering exploit the unique properties of nanoscale materials in order to design and manufacture devices and systems that possess entirely new functionality and capabilities. Nanotechnology is additionally being applied to or developed for application to a spread of commercial and purification processes.

Track 12: Ceramics, Glasses & Composite Materials:

Glass-ceramics have an amorphous phase and one or more crystalline phases and are produced by a so-called "controlled crystallization" in contrast to a spontaneous crystallization, which is typically not wanted in glass manufacturing. The use of those materials in specific areas is predicted to extend within the future, including structural, functional and biomedical applications. Glass-ceramics are utilized in medical applications thanks to their unique interaction, or lack thereof, with physical body tissue. In most cases nucleation agents are added to the bottom composition of the glass-ceramic.

Track 13: Functional Materials:

Functional materials are materials that have one or more properties which will be significantly changed during a controlled fashion by external stimuli and are therefore applied in a broad range of technological devices as for instance in memories, displays and telecommunication. Functional materials are found altogether classes of materials: ceramics, metals, polymers and organic molecules. Functional materials are often utilized in electromagnetic applications from KHz to THz and at optical frequencies where the plasmonic properties of metals assume particular importance.

Track 14: Pharmaceutical Nanotechnology:

Pharmaceutical Nanotechnology applies the methods and principles of Nano science and nano medicine to pharmacy to develop new drug delivery systems to overcome the drawbacks of conventional drug delivery systems. Pharmaceutical nanotechnology helps to fight against several diseases by detecting the antigen related to diseases and also by detecting the microorganisms and viruses causing the diseases. Pharmaceutical Nanotechnology has played a really key role to beat several drawbacks of conventional dosage forms for like tablets, capsules etc.

Track 15:  Nanomaterials in Safety and Regulations

The development of Nano materials has made the entire international affect the advantages of the fast developing discipline of Nanomaterial’s and nanotechnology. A number of manufactured nanomaterials have however been related to health hazards. Research by the scientific committee on emerging and newly identified risks (SCENIHR) has indicated that some nanomaterials are often haunted within the lungs causing inflammation and tissue damage, fibrosis and tumour generation. The main concern are going to be if any of the nanoparticles entering the environment and humans are toxic or could become toxic to living species within the environment.

The Global smart Materials market marked for $36.13 billion in 2017 and is expected to reach $127.04 billion by 2026 growing at a CAGR of 15% during the forecast period. Some are fueling the market are demand for sensors and actuators in Consumer goods and electronics and aerospace & defense. North America is anticipated to exhibit the considerable growth thanks to primarily due to significant demand for smart actuators and motors in key industries like commodity , automotive and aerospace.

The global composites marketplace for core materials is estimated to extend from USD 1.17 Billion to USD 1.92 Billion from 2016 to 2020 respectively and a CAGR of 8.77% is expected between 2017 and 2022. There could also be increase within the market of core materials as manufacturers of materials are signing supply agreements with end-use industries to carry on and improve their market in the composites.

Advanced Materials Market was valued at USD 55,016 million in 2022, and is predicted to succeed in USD 14,741 million by 2015, supported by a CAGR of 20.7%.

Benefits of Attending Materials:

1) Meet Experts & Influencers Face to Face

2) Networking Opportunities

3) New Tools, Innovation and ideas

4) Learning in a New Space

5) Break Out of Your Comfort Zone

6) New Tips & Tactics

7) The Serendipity of the Random Workshop

8) Invest In Yourself

Target Audience:

1. Materials Scientists/Research Professors

2. Physicists/Chemists

3. Junior/Senior research fellows of Materials Science/ Nanotechnology/ Polymer Science/

4. Biotechnology

5. Materials Science Students

6. Directors of chemical companies

7. Materials Engineers

8. Members of different Materials science associations.

9. Polymer companies.