Advanced Materials and Nanotechnology offers an in-depth yet accessible guide to the subject area. It covers the latest developments in this important field, including new applications for nanophase materials based on carbon nanotubes, metallic nanowires/nanotubes, mesoscopic alloys, ferroelectrics, perovskites, luminescent/phosphors, heat-resistant ceramics, polymer composites, etc., through both traditional and non-traditional synthesis techniques.

Biomaterials and Medical Devices is a one-stop source of information on biomaterials and medical devices. It provides extensive coverage on biomaterial characterization, tissue engineering, regulatory issues, and more. The Conference begins with the basics of biomaterials, followed by an in-depth discussion of tissue engineering materials. Regulatory and quality management systems for these materials and device products are also discussed.

Biomaterials are divided into five categories: Ceramics, Glasses, Metals, Polymers and Biological Materials, with particular reference to their application in dentistry, cardiology, orthopaedics, cancer research, and medicine.

The biomaterials market is expected to reach USD 335.77 Billion by 2025, at a CAGR of 19% between 2016 and 2025

Energy garage is the seize of electricity produced at one time to be used later to lessen electricity demand-deliver imbalances. An accumulator, additionally called a battery, is a tool that shops electricity. Radiation, chemical, gravitational potential, electric potential, electricity, multiplied temperature, latent heat, and kinetic electricity are all sorts of electricity. Energy garage involves changing electricity from difficult-to-keep facts to extra effectively or economically storable forms.

Advanced Nano Structural Materials are the next generation of sustainable transport solutions made lighter, stronger, more challenging, more resilient. Structural materials are one of the most promising fields in nanotechnology. The nanostructured material type focuses on mechanical properties only and allows new materials with properties that do not exist in nature. Advanced structural materials, including high-strength steel, advanced composites, and rigid aluminium alloys, are just some of the aerospace industry's advanced materials to build stronger aeroplanes.

Nanomaterials and Nanotechnology is a broad field of research that includes various methods, substances, and particles. Nanotechnology can make existing transformations in medicine, space exploration, electronics, energy & environment, transportation, computer technology and communications. This Conference will take you on a beautiful journey about the future of technology and how it will affect all of us. This Conference takes a multidisciplinary approach to the topic and covers physics, Chemistry, Materials Science, Biomedical Engineering, biologicals or robotics and Electrical Engineering. Many scientists have researched these disciplines in recent years so that their future applications will be more effective and efficient.

The graphene material is a 2D material that is only a single atom thick. It makes it the lightest and thinnest material in the world while also being the strongest and the most flexible. Other highlights of this wonder material include superconductivity, high thermal conductivity, anti-corrosive property, transparency and conductive etc. Graphene has already been used successfully in smartphones, smartwatches, tablets, aeroplanes, baby bottles, bicycles, water filtration, solar cells, batteries, or electrodes and many more.

Metallurgical and Materials Engineering is the study of the microstructure and properties of metals, their chemical compositions, and their processing by heat treatment. Metallurgists are concerned with the physical properties of metals. In contrast, materials engineers are involved with the properties integral to specific end-use, such as steel tensile strength or aluminium compression strength. Material science conference helps attendees gain in-depth knowledge of metals' physical, chemical, and mechanical properties. It also focuses on the material's applications in various industries.

Aerospace and mechanical engineering is a wide range of engineering concepts and technologies, including interactions in physical systems ranging from computer software to aircraft, spacecraft or medical devices. They solve problems in designing and managing products that require high reliability. It is a very opportunity for those who are interested in the field of aerospace and mechanical engineering. The Conference covers a wide range of topics from history, rocket propulsion, and spacecraft building.

Polymers and composite materials are regularly employed as structural components in various applications, including aerospace, transportation, construction, microturbines, and liquid-crystal displays. Renowned for their ability to achieve high strength-to-weight ratios and toughness, synthetic polymers make up an increasing proportion of the total market for energy storage devices.

Polymer composites are typically lighter than conventional materials because their constituent polymers' intrinsic strength and rigidity can be harnessed as a structural component. They are often stronger than steel by weight and sometimes more rigid than aluminium.

Mining and Metallurgy describe ore bodies' physical and chemical characteristics and the equipment and techniques used for their extraction. Mining engineering started as early as 6000 B.C. when people discovered that heat resulted in greater abundance after smelting metal ores.

Mining and Metallurgy session for attendees in the field of mining engineering, geology, mining science, mineral economics, mineral materials, civil engineering, metallurgy, material science, mechanical engineering, in short for everyone in this field.

The mining industry extracts valuable minerals from the earth. It covers the worldwide markets for Coal, Iron Ore, Copper, Zinc, Manganese, Gold, Tin, Lead & Zinc, Aluminium, Nickel & Nickel Compounds, Molybdenum and Uranium.

The Conference delivers a concise and focused treatment of homogeneous and heterogeneous catalysis. All aspects of this topic in the field are present by experts, from fundamentals to application. It contains research or industrial challenge that illustrates both the usefulness and limitations of the discussed techniques and catalysts. This Conference will be valid for advanced undergraduate and graduate courses and researchers in industry, government laboratories, and academia looking to review the latest advances in this constantly developing area.

The Conference is a comprehensive guide for engineers and industry managers concerning surface science and engineering developments, including the modelling of surfaces, coating, thin films, custom advanced materials, materials selection and design, defect creation procedures, surface durability strategies, and many others more.

Materials synthesis and processing is the application of microstructures to gain desirable properties for practical applications. These applications include electromagnetic shielding, thermal management, biocompatibility, and durability (for corrosion resistance). The microstructure of a material is defined as the arrangement or order of its atoms. It can be described as its crystal lattice's size, shape, and orientation. It determines how it reacts to stress from outside influences such as an electric field and heat.

Materials informatics is fundamentally about applying informatics to address problems in materials science and engineering. It seeks to improve both the quality and quantity of our understanding of material properties. It leverages the wealth of information contained within existing datasets, particularly large-scale high throughput experimentation, to facilitate discovery in materials science. Its ultimate goal is to exploit this knowledge to enable more effective materials for products, processes, and design.

The electronics and photonics industry is being reshaped by technologies such as smartphones, digital media, green energy solutions (ultra-efficient solar cells), touch-screen displays, LED lighting (for example, for car lighting), chipsets for new radio technologies (such as wireless power transfer), and biomedical imaging. Some of the more popular manufacturing techniques include printed electronics, photovoltaics (P.V.) (including amorphous silicon (a-Si) and thin-film transistor), light-emitting diodes (LEDs), organic light-emitting diodes (OLED), flexible electronics, organic electronics, solid.

Computational Material Science brings together experts worldwide to present the most up-to-date information and research on Computational Material Science topics. The Conference covers recent advances in the field, such as developing advanced materials for sapphire substrates, advanced alloys; composite materials; quantum materials; and superconductors.

Physical inorganic chemistry is a challenging and extensive subject covering many applications, ranging from understanding global climate change to controlling efficient light-emitting devices, which frees society from carbon fuels without sacrificing its way of life.

Sensor’s technology is central to developing the systems and devices we rely upon in modern life. The portfolio covers a wide range of sensors for mobile, material handling, air quality, temperature, resistive temperature detectors (RTDs), liquid level and flow, and infrared and pressure sensors.

The sensors can convert another form of energy into a signal that may be analyzed by an observer or by additional sensors.