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Theme
"Congregation to endow, enrich and foster the knowledge hunters in the Materials & Metals World"
- Materials-Metals 2017

About Conference

Allied Academics is proud to announce its 13th Annual Conference on Materials Science, Metal and Manufacturing, which is to be held during November 16-17, 2017 in Paris, France. On this great gathering, Organizing Committee invites participants from all over the globe to take part in this annual conference with the theme"Congregation to endow, enrich and foster the knowledge hunters in the Materials & Metals World". Materials-Metals 2017 aims at sharing new ideas and new technologies among the professionals, industrialists and students from research areas of Materials Science, Metals and Metallurgical manufacturing to share their recent innovations and applications in various fields and indulge in interactive discussions and technical sessions at the event. The Conference will also have a space for companies and/or institutions to present their services, products, innovations and research results.

Materials-Metals 2017 involves the tracks like Materials Science and Metamaterials Engineering, Advanced Metal extractions, Metallurgy & Metalworking Processes, Advanced metal casting, metal forming & Steel making, Surface Coatings Technology and Thin Films, Non-Ferrous Metals, Alloys & Welding Metallurgy, Biomaterials, Biodegradables and Biomimetics, Energy Materials, Devices & Superconductors, Smart & Hybrid materials, Graphene, Fullerene, Semiconducting and 2D materials, Polymers and Condensed Matters, Nanomaterials & Microstructures, Electronic, Optical, Magnetic & Multiferroic Materials, Computational Modelling, Processing & Simulation of Metals & Materials, Photovoltaic, Photonic and Thermoelectric materials, Crystalline, Semi-crystalline and Non-Crystalline materials, Textile Fabric & Fiber Materials, Recycling & Reuse of Materials & Metals and Forensic and Corrosion Science.

Importance and Scope:

Materials science has been pushed to the forefront of research and development not only in universities but in industries as well. With the planet's resources being mined each day in order to supply the growing demands of industrialization, one major task of materials science is to revolutionize the manufacturing industry with the best materials for manufacture that are sustainable for the long term. Materials science is also paving the way for new theoretical and empirical research in areas of physics, engineering and chemistry

Materials and metals plays a vital role in our lives because of its uses and applications in almost in every industry like packaging, sports, medicine, perfumes and preservatives, plastics, fuels, toys etc. Metals are also used in the manufacture of Prosthetic devices and surgical equipment. The diversity of use is growing day by day. The history of metals is not a long one. They are beginning to emerge as a result of needing to be more responsible in taking care of the world we live in. Various reasons are associated with the research and development of materials and metals. The use of metals and materials could markedly increase as more durable versions are developed, and the cost to manufacture these metals and composites continues to go fall. Bio-plastics can replace conventional plastics in the field of their applications also and can be used in different sectors such as food packaging, plastic plates, cups, cutlery, plastic storage bags, storage containers or other plastic or composite material items you are buying and therefore can help in making environment sustainable.

Materials and metals have wide application in industries like aerospace, automobile etc. It also finds application in specific products like fishing rods, bicycle, sports equipment etc. Polymer engineering consists of many aspects of petrochemical industry and polymerization. Polymer engineering covers many aspects related to chemical engineering. Plastics are also used in the manufacture of Prosthetic devices and surgical equipment. The diversity of use is growing day by day. Many Polymer processing societies has been developed in recent years. The aim of these societies is to foster scientific understanding and technical innovation in polymer processing by providing a platform forum for the worldwide community of engineers and scientists in the field.

 

Why to attend???

13th Annual Conference on Materials Science, Metal and Manufacturing -2017 which is going to be the biggest conference dedicated to Materials science professionals providing a premier technical forum for reporting and learning about the latest new generation technologies developed during the course of time along with discussing  their applications. Events include hot topics presentations from all over the world and professional networking with industries, leading working groups and panels.

Meet Your Objective Business sector With individuals from and around the globe concentrated on finding out about Materials science and Metals, this is the best chance to achieve the biggest collection of members from  everywhere throughout the World. Conduct shows, disperse data, meet with current, make a sprinkle with another product offering, and get name acknowledgment at this occasion. Widely acclaimed speakers, the latest methods, strategies, and the most up to date overhauls in Materials science and Metals are signs of this meeting.

Target Audience:

  • Materials Science Scientists.
  • Materials Science Professors.
  • Research Scholars and students
  • Metallurgical Industries
  • Materials Associations
  • Metallurgical and Material Science Engineers

Welcome Message

Allied Academics invites all the participants across the globe to attend the 13th Annual Conference on Materials Science, Metal and Manufacturing (Materials-Metals-2017) during November 16-17 in Paris, France with the theme "Congregation to endow, enrich and foster the knowledge hunters in the Materials & Metals World" with an objective to encourage young minds and their research abilities by providing an opportunity to meet the experts in the field of Materials Science & Metals.

Materials-Metals 2017 event is designed to explore various applications in different fields. Allied Academics organizes a conference series of 3000+ Global Events with over 600+ Conferences, 1200+ Symposiums and 1200+ Workshops in USA, Europe & Asia with support from 1000 more scientific societies and publishes 700+ Open access journals which contains over 30000 eminent personalities, reputed scientists as editorial board members.

Allied Academic Publication is an amalgamation of several esteemed academic and scientific associations known for promoting scientific temperament. Established in the year 1997, Andrew John Publishing Group is a specialized Medical publisher that operates in collaboration with the association and societies.  This publishing house has been built on the base of esteemed academic and research institutions.

Sessions/Tracks

Track 1: Materials Science and Metamaterials Engineering

Materials, in a wider point of view are substances which constitute an article or object or organism, be it microscopic or macroscopic. In a scientific approach, it is the composition factor of all matter. Based on the properties, like chemical, physical, geological & biological, it can be sub classified into various groups based on their uniqueness.

Materials science is the study of these materials, based on their structure, bonding, and their various characteristic properties like physical, chemical, mechanical, kinetic and thermodynamic properties. It is also the study of their processing, fabrication, integration and application.

All courtesy to the boon of nature, science and relentless effort of people who strive to make our lives better, we are now amongst the labyrinth of array of materials ranging from electrical, optical, biological, macroscopical & microscopical and the list goes on.

Metamaterials are substance in which characteristics and features have been induced in them physically or chemically, which they had not inherited naturally. They range from programmable matter which was instructed to perform specific functions under specified conditions.

This track is to enrich and endow the latest upcoming technologies to harness existing and upcoming materials, their processing, fabrication & application and advantages over regular materials and the potential they hold for our future generations.

Track 2: Advanced Metal extractions, Metallurgy & Metalworking Processes

Metal is one of the blessings that we had inherited from the nature and they had been with us since the beginning of time and their importance and application to our day to day life is indispensable. As far as the definition is concerned it is a solid hard material and shows general typical properties like hardness, opacity, electrical and heat conductivity and is also ductile and malleable.

Metals have always been our tools & structure since our primitive stage to our modern age. There has been transition in the way application of metals but their presence was never undeniable. With time we have discovered new methods of mining, detection of ores, extraction and fabrication. We have devised new methods like electrolysis, smelting, hydrometallurgy, pyro metallurgy, forging, rolling and various heat treatment and metal working processes to obtain metal articles of desired shape and size.

Track 3: Advanced metal casting, metal forming & Steelmaking

In the present generation we did not restrict ourselves to getting the basic benefits of metals we walked some extra miles to upgrade the properties of metals and reap better benefits from them. We have coined processes like plating, coating and galvanizing to inhibit corrosion processes and enhance strength and durability properties. The study of plastic deformation of metals has helped to shape them accordingly and work on building their compressive and tensile strength. Metal subject can now be used and fabricated as per its bending, shearing and load bearing capabilities.

Extensive study and research on the most widely use metal like iron has enabled us to create various versions of steel and reap its benefits as steel has always been known to be the most technically and feasible metal alloy.

Track 4: Surface Coatings Technology and Thin Films

To inhibit and protect articles from various damage causing forces of nature we have synthesized materials like paints, coatings and varnishes to help protect them and ensuring a longer service life. The coatings also have aesthetic benefits along with functional benefits which gives a tempting pigment and desired finishing effect. The coatings are applied on desired surfaces involving various processes likewise chemical vapor deposition and physical vapor deposition. The functional benefits that we acquire from these developed coatings are like protective, optical coating, insulation, waterproofing, antimicrobial and antifouling benefits.

One of the most researched aspects of coatings presently is the Thin Films.  The thin layer comprising the film maybe ranging in size from a few micrometers to a fraction of a nanometer and it has got innumerous application from electromagnetic devices, optical media, semiconductors, thin film, photovoltaic cells etc. The sheer space saving property of these thin films makes it energy saving, economical and versatile.

Track 5: Non-Ferrous Metals, Alloys & Welding Metallurgy

Several metals, though not having a ferrous background have shown vast scope of advantages and unique properties which makes it appropriate for specific application, for example the conductivity of copper, the nonreactive property of noble metals like gold, silver and platinum, the structural integrity and tensile strength of titanium, lightweight and corrosion resistant property of aluminum etc. With passage of time we have devised several methods of their fabrication and tremendous scientific trials have led us to generating of their alloys which are superior to their parent metals in all aspects.

Another trending aspect in metallurgy is Welding Metallurgy. Welding as we all know is the science of joining materials. But welding metallurgy is the science of study of interaction of different metals and interaction of metals with different gases and chemicals to produce exceptionally potent articles in terms of structural, physical and chemical integrity. This has enabled us to create extremely durable, lightweight and stress-stain bearing alloys which are extensively used for aerospace engineering, space missions and high wear and tear involving processes.

Track 6: Biomaterials, Biodegradables and Biomimetics

Biomaterial is a substance which has been engineered in a way that they are biocompatible with biological systems and provide therapeutic or diagnostic benefits.  The science of biomaterials has amalgamated the knowledge of chemistry, biology, medicine, tissue engineering and materials science. The biomaterials are used as key materials for transplants, biomaterial implants, autograft, allograft or xenograft, regenerative medicine, scaffolds and has innumerous other application.

Biodegradables are materials which possesses functional benefits, but on the other hand they are super eco-friendly as they interact with the environment harmlessly and they degrade easily after their operational lifetime causing no additional pollution and leads a path towards a sustainable environment.

Biomimetics are materials that solves complex human problems as although being manmade they interact and behave like naturally occurring materials as they can mimic the inherited the natural behavior of natural materials. They are now finding vast application in fields like artificial enzymes and photosynthesis and have shown tremendous scope of future application.

Track 7: Energy Materials, Devices & Superconductors

With the coming age we are bound to face a severe energy resource crisis due to the fast depleting fossil fuel reserves. This is where the energy materials come to rescue, for example the photovoltaic cell and solar power systems which derives energy from the virtually inexhaustible sunlight, the radioactive materials from which tremendous amount of energy can be derived via nuclear fission or nuclear fission, and thermoelectric which generates electricity on being heated etc.

These energy materials has led to the devising of several devices which harnesses, conducts and transports energy efficiently. Devices like super capacitors, fuel cells, thermoelectric and piezoelectric materials have been invented, which aids in energy production, transmission and storage.

To ensure loss less transfer of the energy produced and efficient power output superconductors have been produced superconductors have been devised. Superconductors are basically devises which transmits electricity in a lossless manner. It has got a promising future in enhancing spintronic devices, transformers, smart grid, electric power transmission, electric motors, power storage devices, magnetic levitation devices and fault current limiters.

Track 8: Smart & Hybrid materials

Materials which are generally comprised of dissimilar phases which shows significant change in their properties when imposed by an external stimuli for example magnetic or electric field are known as smart materials. In general smart materials are a combination of two or more materials upon which the desired properties are allowed to be expressed. Process control, modeling and simulation aids in fabrication of smart materials. Various smart materials have been fabricated like the smart memory alloys which retain their original shape when heated even after going through a plastic deformation and materials like ferroelectrics and piezoelectrics which produce electric current when imposed by a mechanical stress.

Hybrid Materials are kind of a smart material at a nanometric or molecular. It is generally comprised of two or more constituent one being organic and the other being inorganic. The inorganic part provides the mechanical advantage, whereas the organic part provides the functional advantage. Till date we have got several hybrid materials which aids in corrosion resistance, fire resistance, anti-oxidizing agents etc.

Track 9: Graphene, Fullerene, Semiconducting and 2D materials

One of the recent major trending subject of discussion are the allotropes of carbon like Graphene & Fullerene. Graphene a two dimensional carbon comprised material has shown miraculous properties in terms of strength, light weight and exceptional heating and conducting property, also it is the only allotrope of carbon in which all its reacts from both sides. This compound has raised many eyebrows and it is being researched for various methods of synthesis and for integrating potential its tremendous potential in our day to day life, in devices like semiconductors, biosensors and other 2D materials.

Another form of the carbon allotrope which is undergoing extensive research is fullerene, which is a molecule of carbon in the shape of a ball which has shown many exciting properties among which superconductivity is the most commendable one. It is now widely used for several biomedical applications like photodynamic therapy, drug and gene delivery and also in the design of high-performance X-Ray imaging contrast agents and MRI contrast agents.

Track 10: Polymers and Condensed Matters

Polymers have been all around with us since the beginning of time; they formed the very basis (building blocks) of life i.e the natural polymers. Animals, plants and all classes of living organisms from the microscopic to macroscopic level, are composed of polymers. However, it was not as late as the middle of the 20th century that we began to understand the true nature of polymers. This understanding about the Polymer world came with the development and synthesis of plastics, which are true man-made materials that are the ultimate tribute to man’s innovative power and finesse. As we shall see in following conference, the use of polymeric materials has permeated every facet of our lives. It is now even impossible to imagine today’s world with all its luxury and comfort without man-made polymeric materials.

With the passage of time, we have now been able study polymers in details which have further allowed Polymer Characterization by New and Combined Techniques. Produce Bio-polymers, advanced elastomeric materials and supra-molecular polymers which can undergo self-assembly. Go ahead with modeling and simulation of polymers. It has been even further applied it in the Bio-medical field, energy application field like sensors.

Condensed matter is a branch of physics which involves the physical properties of condensed phases of matter that is when particles stick or adhere to each other. Physicists of this field strive to understand the behavior of these phases by the knowledge and application of physical laws like laws of electromagnetism, quantum mechanics and statistical mechanics.

Research in this field has given rise to several device applications, such as the development of the laser technology, semiconductor, transistor and several phenomena studied in the context of nanotechnology. It has also aided to the study of scanning-tunneling microscopy which can be used to control processes at the Nano metric level and led to the inception of nano fabrication.

Track 11: Nano-materials & Microstructures

Nano materials are set of a broadly classified substance that have at least one critical dimension less than 100 nano-meters and possesses unique bonding, structural, magnetic, optical and electrical properties. Ultra fine particulate matter is a well-known example of nano-materials particles found in the environment. These materials with typical size of lower than a nano-meter size range and characteristic mesoscopic properties, like the quantum size effects. These inherent properties make them trending subjects of fundamental research and for the devising of potential new applications.

Micro structures are minute structures of a material and can be visually revealed by a microscope having more than 25 x magnifications. Various materials like metals, polymers, ceramics and composites have microstructures and they deeply influence various properties of the substance like high/low temperature behavior, wear and tear resistance, strength, toughness, hardness, ductility etc. Microstructures can be further classified into nanostructure, crystal structure and ultrastructure based on the size and composition material. The in depth knowledge about microstructures helps to engineer materials and inhibit point defects, crystal defects and bonding defects.

Track 12: Electronic, Optical,  Magnetic & Multiferroic Materials

Materials have a tendency to show various inherent properties namely electrical, optical, magnetic property etc. the properties of materials allow us to take advantage of it and integrate it into our day to day life. But the materials that we get from the nature are in the crude form i.e not pure form, hence they need to be synthesized, processed, fabricated and then integrated into our lifestyle. Research of these materials also enables to synthesize superior grade materials by combining two or material and produces a material superior than their parent materials. Electronic materials of these types are widely used in sensors, conductors, capacitors, loss less transmission devices etc. The advanced optical material s are used in imaging, microscopy, spectroscopy, laser physics, X-rays, optical wires telecommunication etc. Magnetic materials are used in superconductors, audiosystems, data recording, motors, generators, transformers, compasses etc.

Multiferroics are a special type of magnetic material that shows multiple characteristics like ferromagnetism, ferroelectricity & ferroelasticity. This advanced group of material is now being extensively used in spintronics, tunnel magnetoresistance, filters, oscillators, phase shifters etc.

 

Track 13: Computational Modelling, Processing & Simulation of Metals & Materials

Computational materials science is an extensive field which holds tremendous future potential. It plays a vital role in the modern and vast approach to the development of materials. However, its approaches have to be developed to be even more robust, systematic and connected to the rapidly growing materials databases .This is the heart of modern research and development. Materials modeling involve several types of tools such as finite element and finite-difference methods for solving continuum equations in mechanics, fluid dynamics and diffusion, or free-energy minimization programs for phase equilibrium. Electronic structure calculations, atomistic and molecular dynamics, kinetic and statistical modeling, together with new and emerging techniques and increased computational techniques can provide answers to versatile and complex questions related to materials properties, manufacturing, performance and technological applications. Simulation of the materials and metals can be used in many aspects such as simulation of technology for safety engineering, training, testing, education and performance optimization.

Track 14:  Photovoltaic, Photonic and Thermoelectric materials

Photovoltaic are a special branch of material which converts light to electrical energy using semiconductors which is also known as the photovoltaic effect and this subject amalgamates the knowledge of materials, physics, electrochemistry and photochemistry. These materials extensively used in solar cells and solar power systems.

Thermoelectric materials are materials which create an electric potential and allows production of electricity when a temperature difference is applied to them and vice versa. These materials have been extensively used for power generation and refrigeration.

These materials have turned out to be a boon for the world, since the world is going to face a severe energy crisis in the upcoming days and these materials promises to provide the most appropriate alternative. Another reason for their increasing popularity as these materials poses no environmental hazards as they result to little or no pollution.

Photonic materials are optical materials on which various physical phenomena of light takes place photon generation, detection, and manipulation through emission, transmission, modulation, signal processing, switching, amplification, and detection/sensing and these materials are widely used in today’ s world in laser, gyroscope, optical fibers, microscope, chromatography, spectrography, telecommunication etc.

 

Track 15: Crystalline, Semi-crystalline and Non-Crystalline materials

The purpose of processing crystalline, semi-crystallline and non-crystalline to applied science is to enhance the innate ability present in them and to develop, characterize and refine these materials. The crystallinity of these materials ranges from crystalline to highly-oriented to semi-crystalline, and often completely amorphous (e.g., glasses). Varying crystallinity and and notable properties makes them extensively researched topic in materials engineering. This track covers Phase equilibria, Mechanical behavior and failure mechanisms and Microstructure Development, Sol-gel techniques, Powder Consolidation/Powder Synthesis and thin film deposition. It also includes the chemistry of these substances, study on quasicrystals and liquid crystals, crystalline novel materials, composite ceramic coatings, composites, functional and nuclear ceramics. It has been also formulated in a way to endow the extensive research in macromolecular crystallography, organic frameworks, semi crystalline and liquid crystal polymers. In depth study of these crystallographic defects will ensure the eradication of the defects in the root level.

Track 16: Textile Fabrics & Fiber Materials

Textile fabrics, is a branch of materials which is flexible and comprises of a network of artificial or natural fibers. It is extensively used for apparel purposes. It is made through processes like weaving, knitting, spreading, crocheting, or bonding after which it is used for apparel purposes. It is of various origins from plant to animal derivatives. Most recent advances in textiles industries include eco-friendly textile and textiles produced from residues like waste and residues. This track deals with the various processing techniques and fabrication of textiles.

Fiber is a kind of a special substance which has a special characteristic of being longer than being wide. It can be both natural and synthetic. It can be soft and brittle and can be also stronger than reinforced steel e.g carbon fiber. We have now produced useful fibers from various materials like metallic fibers, optical fiber, silicon carbide fibers, fiber glass, microfibers and mineral fibers which are now being extensively used.

Track 17: Recycling & Reuse of Materials & Metals

This is a more of an environment based track which sought to curb the pollution and environmental hazard the unneeded materials posed when their operational lifetime is over and how they can be put to ensure further benefits in an environment friendly way and also in a more economical, technical and functional way. General methods include processing of E-waste, plastic and material waste. It also includes the disseminating the knowledge of advantages and process of recycling and reuse. It also emphasizes on processes like remanufacturing, repurposing and sustainable growth, which further aids in the conservation of natural resources.

Track 18: Forensic and Corrosion Science

Forensic & corrosion science is the study of failure in materials. The track includes the study of fracture of materials & products, or any other possible reason why such a product fails in service or fails to meet its specification it was created for. It also includes the various methods of analysis of the product failure. Few of the causes include exposure to ozone and UV causing ozone degradation and UV degradation respectively, exposure to chlorine resulting in chlorine induced cracking and exposure to water causing hydrolysis. Research on forensics and study on the factors of corrosion helps us understand the reason of failures of materials and metals and what agents have possibly caused the failure and what approaches can be taken to prevent the occurring of similar circumstances. It involves the study of structural failure, stress-strain analysis, forensic chemistry and fractography. This knowledge helps us synthesizing additives and reagents that help in corrosion control, corrosion prevention & corrosion repair.

 

Maket Analysis

Importance and Scope:

Materials science has been pushed to the forefront of research and development not only in universities but in industries as well. With the planet's resources being mined each day in order to supply the growing demands of industrialization, one major task of materials science is to revolutionize the manufacturing industry with the best materials for manufacture that are sustainable for the long term. Materials science is also paving the way for new theoretical and empirical research in areas of physics, engineering and chemistry

Materials and metals plays a vital role in our lives because of its uses and applications in almost in every industry like packaging, sports, medicine, perfumes and preservatives, plastics, fuels, toys etc. Metals are also used in the manufacture of Prosthetic devices and surgical equipment. The diversity of use is growing day by day. The history of metals is not a long one. They are beginning to emerge as a result of needing to be more responsible in taking care of the world we live in. Various reasons are associated with the research and development of materials and metals. The use of metals and materials could markedly increase as more durable versions are developed, and the cost to manufacture these metals and composites continues to go fall. Bio-plastics can replace conventional plastics in the field of their applications also and can be used in different sectors such as food packaging, plastic plates, cups, cutlery, plastic storage bags, storage containers or other plastic or composite material items you are buying and therefore can help in making environment sustainable.

Materials and metals have wide application in industries like aerospace, automobile etc. It also finds application in specific products like fishing rods, bicycle, sports equipment etc. Polymer engineering consists of many aspects of petrochemical industry and polymerization. Polymer engineering covers many aspects related to chemical engineering. Plastics are also used in the manufacture of Prosthetic devices and surgical equipment. The diversity of use is growing day by day. Many Polymer processing societies has been developed in recent years. The aim of these societies is to foster scientific understanding and technical innovation in polymer processing by providing a platform forum for the worldwide community of engineers and scientists in the field.

 

Why to attend???

13th Annual Conference on Materials Science, Metal and Manufacturing -2017 which is going to be the biggest conference dedicated to Materials science professionals providing a premier technical forum for reporting and learning about the latest new generation technologies developed during the course of time along with discussing  their applications. Events include hot topics presentations from all over the world and professional networking with industries, leading working groups and panels.

Meet Your Objective Business sector With individuals from and around the globe concentrated on finding out about Materials science and Metals, this is the best chance to achieve the biggest collection of members from  everywhere throughout the World. Conduct shows, disperse data, meet with current, make a sprinkle with another product offering, and get name acknowledgment at this occasion. Widely acclaimed speakers, the latest methods, strategies, and the most up to date overhauls in Materials science and Metals are signs of this meeting.

Target Audience:

  • Materials Science Scientists.
  • Materials Science Professors.
  • Research Scholars and students
  • Metallurgical Industries
  • Materials Associations
  • Metallurgical and Material Science Engineers
  • Market Analysis:

    Materials science is evolving every day. Millions of chemical and material combinations create challenges for scientists when applying them to real world applications that consumers touch every day. Keeping abreast of the latest trends in material science across a wide range of industries can be a daunting task. A range of new materials with advanced properties are created through the process of technological development and knowledge intensive production. These are known as Value Added Materials (VAMs). New materials appear all the time in the natural course of industrial development however advanced materials are tailored to fulfill specific functions and/or have superior structural properties. The global market is projected to reach $6,000 million by 2020 and register a CAGR of 10.2% between 2015 and 2020 in terms of value. The growth in market is estimated to be driven by the increasing demand for aerogel materials from oil & gas and construction applications. The North American region remains the largest market, followed by Asia-Pacific. The Europe market is estimated to be growth at a steady rate due to economic recovery in the region along with the increasing concern for the building insulation and energy savings.

    Scientific’s index of countries' ability to take advantage of emerging technologies indicates that the US, Germany, Taiwan and Japan have the combination of academic excellence, technology-hungry companies, skilled workforces and the availability of early stage capital to ensure effective technology transfer.


  • Nanotechnology Industry Focus

    The global market for biomaterials is estimated at $44.0 billion in 2012 and is poised to grow at a CAGR of 15% from 2012 to 2017 to reach $88.4 billion by 2017. The biomaterial polymers market is expected to show the highest growth at a CAGR of 22.1% (2012-2017) due to tremendous on-going research for the development of biodegradable and bio-compatible polymeric biomaterial and its use in a wide range of applications. 



  • Growth forecast of Biomaterials.

    The global high performance alloys market is expected to rise and reach US$9.09 billion by 2020, from a value of US$6.82 billion in 2013. . In terms of volume, the market stood at 1,110.7 kilo tons in 2013. Overall, the market is expanding at a steady CAGR of 4.2% during the forecast period from 2014 to 2020.



  • Global high performance alloys market by region (Kilo Tons)

    The ceramics market is forecast to grow to USD 502.8 billion by 2020, According to global market analysis, in 2014, the Composite materials industry is expected to generate revenue of approximately 156.12 billion U.S. dollars.



  • Global MMC Market revenue

    The silicon photonics market is expected to grow to $497.53 million by 2020, growing at a CAGR of 27.74% from 2014 to 2020. The silicon carbide semiconductor market is estimated to grow $3182.89 Million by 2020, at an estimated CAGR of 42.03% from 2014 to 2020.



  • Growth forecast of semiconductor industries. (In Million Dollars)

    BCC Research projects that the total global market for meta materials is expected to grow about $1.2 billion by 2019 and nearly $3.0 billion by 2024, registering a compound annual growth rate (CAGR) of 20.5% between 2019 and 2024. The global market for smart materials totaled about $26.0 billion in 2014 and is expected to reach $42.2 billion in 2019, registering a compound annual growth rate (CAGR) of 10.2% for the period 2014-2019.



  •  Growth forecast of Fibre optics industries. (In Million Dollars)

    Market size for Value Added Materials is foreseen to grow much faster than the average growth of analyzed industrial sectors. At the request of the European Commission, study authors invited experts to give their opinions about these developing VAM markets. Materials experts as well as financial advisors and investors who are directly engaged in related investments contributed to this inquiry. Willingness of the investors in the area of energy, environment, health, information communication and technology is represented graphically in the following way.

    Investment willingness for VAMs in ICT sector:

    Within the energy sector — which promises the most growth potential in the future— our study indicated the biggest potential in the energy storage field, which garnered one-third of the possible investments. This indicates that batteries and energy storage in large grids are critical issues for future development of many areas of the economy


  • Source: Oxford Research AS. Percentage calculated from averages based on values of portfolio allocation (n=3).

    Investment willingness for VAMs in health sector:

    The health sector is largely dominated by large drug manufacturers with their research- oriented agendas and own laboratories. Still the health sector is very interesting for VC and PE (Venture Capital and Private Equity) in terms of producing medical equipment, new technologies for diagnosis and their related substances. Delivery of prostheses and biomaterials for regenerative medicine is considered a huge market for intensive development in the future. These are seen as highly profitable niche markets where a high innovativeness and knowledge intensively play crucial roles.



  •  Oxford Research AS. Percentage calculated from averages based on values of portfolio allocation (n=5).

     Investment willingness for VAMs in environment sector:

    The willingness to invest in the environmental sector was focused on water technologies

    All areas — from water treatment, desalination to waste water technologies— took up to 48 per cent of the potential investments. Another prospective area was solid waste management and related technologies (also related to technologies focusing on energy production from solid waste). These subsectors take more than three quarters of total environmental sector allocations.



  • Source: Oxford Research AS. Percentage calculated from averages based on values of portfolio allocation (n=5).

     Investment willingness for VAMs in the energy sector:

    Within the energy sector — which promises the most growth potential in the future— our study indicated the biggest potential in the energy storage field, which garnered one-third of the possible investments. This indicates that batteries and energy storage in large grids are critical issues for future development of many areas of the economy.



Source: Oxford Research AS. Percentage calculated from averages based on values of portfolio allocation (n=10 
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Organizing Committee
OCM Member
Marie-Paule Pileni
Distinguished Professor & Senior Researcher, Faculty of Science
University Pierre et Marie Curie
Paris, France
OCM Member
C. Suryanarayana
Professor, Department of Mechanical and Aerospace Engineering
University of Central Florida (UCF)
Orlando, USA
OCM Member
Abdel Salam Hamdy Makhlouf
STAR Full Professor, Manufacturing & Industrial Engineering Department
University of Texas Rio Grande Valley
Dallas, USA
OCM Member
Yuyuan Zhao
Professor, Materials Engineering
University of Liverpool
leicester, United Kingdom
OCM Member
Filippo Berto
Chair of Mechanics and Materials, Mechanics and Materials
Norwegian University of Science and Technology
Trondheim, Norway
OCM Member
Hui Tong Chua
Chemical Engineering Programme Chair, Professor of Mechanical and Chemical Engineering
The University Of Western Australia
Melbourne, Australia
OCM Member
Ivoyl P. Koutsaroff
Principle Engineer, Technology R&D
Qualcomm Technologies Inc.
Florida, USA
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Conference Date November 16-17, 2017
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Insurance: Registration fees do not include insurance of any kind.

Transportation: Please note that any (or) all transportation and parking is the responsibility of the registrant.

Press/Media: Press permission must be obtained from Allied Academics Conferences Organizing Committee prior to the event. The press will not quote speakers or delegates unless they have obtained their approval in writing. The Allied Academics is an objective third-party nonprofit organization. This conference is not associated with any commercial meeting company.

Requesting an Invitation Letter: For security purposes, letter of invitation will be sent only to those individuals who had registered for the conference. Once your registration is complete, please contact lucygrey@conferenceseries.com to request a personalized letter of invitation.

Regarding refunds, all bank charges will be for the registrants account.

This cancellation policy was last updated on April 04, 2015.

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