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  • Material Science and Engineering
  • Novel Materials Synthesis and Fabrication Technologies
  • Materials Technology for 3D Printing Innovation
  • Smart Optical Materials and Device Applications
  • Integrated Nano and Micro- Structures
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Abstract Submission

Final Round Registration

Scientific Committee

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Saint-Gregoire Pierre

Professor at Université de Nîmes, France , President at Collaborating Academics, France

Pierre SAINT-GRÉGOIRE has been researcher in CNRS (National Centre for Scientific Research), France - Montpellier university and Toulouse (CEMES laboratory) before reaching a position of professor (Toulon  university). He was also involved in Africa as professor and special adviser of african ministers for high education and research for development. He works in the fields of structural phase transitions, incommensurate phases, ferroic materials, and materials for photovoltaics, in which he published about 150 articles and, as guest editor two special issues (journals ISJAEE, and Ferroelectrics). He is involved in several  scientific journals (including open access) and in series of scientific meetings. He is now the president of the NGO Collaborating Academics. Defensor of academic freedom, he is also convinced that « Science is the motor of development, and knowledge is a powerful tool against poverty », and is nowadays fully involved in international collaborations, development, scientific communication, and open scientific edition.

Bahram Nabet

Professor, Drexel University, USA

Bahram Nabet received his PhD degree from the University of Washington, Seattle, WA, USA and is presently Professor of Electrical and Computer Engineering, and Affiliated Professor of Materials Science and Engineering at Drexel University, Philadelphia. His research interest was in the interaction of light and biological matter, bio memetic. He produced optoelectronic circuitry influenced by insect eye leading to his first book “Sensory Neural Networks: Lateral Inhibition” published by CRC press, reissued in 2018. His more recent research interests are in information transfer without charge transport, and optoelectronics of the interaction light with reduced dimensional systems. This has led to his recent edited volume on "Photodetectors", published by Elsevier. He is co-author of over 200 publications, including 8 books and book chapters, and is on the editorial board of several journals.

Lluis M. Martinez

Founder and CSO, SEPMAG SYSTEMS, Parc Tecnologic del Valles (Barcelona), Spain

Lluis M. Martinez, Chief Scientific Officer at SEPMAG SYSTEMS, Parc Tecnologic del Valles (Barcelona). After completing his PhD in physics at the at the Autonomous University of Barcelona (1998), he joined Magnetic Solutions Ltd (Ireland) as MSCA fellow, where he continued his research on magnetic materials for advanced applications. Two years later, he co-founded ATIPIC  company (Parc Tecnologic del Valles, Barcelona) to provide advanced research services to the Industry. He authored and  co-authored several International patents on the use of magnetic sensors and materials for Automotive, Textile, and InVitro Diagnostic industries.

In 2007 he founded SEPMAG company to exploit the patented technology for controlled biomagnetic separation.  He has been collaborating with academic institutions (ICMAB,  UAB, U Minho), developing theoretical models for understanding the physical factors governing magnetophoretic processes. The patented systems are currently in use by leading IVD-manufacturing companies worldwide.

Juan J. del Campo Gorostidi

Founder & CEO, Corporate Development Services, S.L. Spain

Juan J. del Campo has developed a 46 years academic and professional international career in Metallurgy. With a degree in Mining Engineering from the University of Oviedo he has conducted fundamental and applied research in Aluminium Smelting and Physical Metallurgy at the Universities of Lyon, Trondheim and Oviedo. In 1984 he obtained a Ph.D. in Materials Science with a thesis that was recognised with the extraordinary University of Oviedo award. He has also been full professor of Materials Science at the Engineering School of Gijón. At the same time he has been able to develop a successful professional career in the metal industry holding different roles at renowned companies such as Endasa-Alcan and ThyssenKrupp from technologist and plant manager in the early years to MD and CEO. He is currently a well-known independent metal corrosion consultant focused mainly on renewable energy plants and continues being reference in the aluminium industry. He speaks fluent Spanish, English and French as well as has good understanding of German.     

Chris Worrall

Principal Project Leader, TWI Ltd., Cambridge, United Kingdom

Chris Worrall is a Principal Project Leader at TWI responsible for composites joining, manufacture, processing and testing. He is a metallurgy and materials science graduate, with a PhD in the impact of composite sandwich materials. Chris has spent ten years in Japan working in the automotive, aerospace, renewable energy and rail transport industries. Before leaving the UK, he worked in a research laboratory on the processing of novel thermoplastic composite materials, improving the toughness of composites, and developing test methods for composite materials. His 30 years of composites experience covers composite-to-metal joining, electromagnetism & dielectric characterisation, mechanical testing of composite materials, finite element analysis, design of composite structures, and manufacturing technology for composite materials. Chris is part of the Surflow™ team at TWI that recently won the Composites UK Innovation award.

Gholamhossein Liaghat

Professor at Tarbiat Modares University (Tehran,Iran) and , Kingston University (London,UK)

Gholamhossein Liaghat holds a PhD, and MSc from the UMIST Manchester, UK and BSc from Shiraz University in Mechanical Engineering. Before joining to Kingston University as visiting professor in 2012, he has been working for Tarbiat Modares University, Tehran, Iran (1990-present). He acts as Postgraduate Research Director (PGRC), and Head of the Applied Mechanics Engineering group. He had taught in UG and PG programs in School of Mechanical Engineering since 1990. He directed more than 115 MSc and 30 PhD projects and so far he completed supervision of 25 PhDs. His work experience includes a professorship at Tarbiat Modares University, as well as several visiting professor appointments at Kingston University. He has led a number of research projects in the area of Impact mechanics and High speed metal forming. He contributed about 114 papers and 4 books to the open press.

Johan Böhlmark

R&D Manager , Lamina Technologies, Switzerland

Johan Böhlmark is the Group R&D Manager at Lamina Technologies in Switzerland. He holds a PhD in thin film physics from Linköping University, Sweden. The area of research was within High Power Impulse Magnetron Sputtering (HIPIMS), with special focus on plasma characterization. During 2006 – 2008, Johan was the CEO of a start-up company named Chemfilt Ionsputtering AB, that developed and sold power supplies for HIPIMS processes. In 2008, he joined the Sandvik Coromant organization, where he for the next 8 years worked within R&D of industrial cutting tools. Johan held several different positions, such as project manager and R&D Manager. In 2016 he accepted a position as Business Advisor for Umea University Holding AB. Since 2018 he is in his current role at Lamina Technologies.

Karin Larsson

Professor, Uppsala University, Sweden

Karin Larsson is a Professor in Inorganic Chemistry at the Department of Chemistry-Angstrom Laboratory, Uppsala University, Sweden. She received a PhD in Chemistry in 1988. The research was directed towards investigation of molecular dynamic processes in solid hydrates by using solid state NMR spectroscopy. In 1989-1990 she worked with Chemical Vapour Deposition (CVD) of diamond thin films, and from 1991 and onwards she has been active in the field of theoretical modelling using quantum mechanical methods (mainly DFT). The scientific focus is thereby on interpretation, understanding and prediction of the following processes/properties for both solid/gas interfaces, as well as for solid/liquid interfaces; i) CVD growth, iii) interfacial processes for renewable energy applications, and iv) interfacial processes for e.g. bone regeneration (incl. biofunctionalisation of surfaces). 

Abdel Salam Hamdy Makhlouf

Professor, Central Metallurgical Research & Development Institute, Egypt

Makhlouf experts 26 years and possesses a blend of industrial and academic leadership experience as a Full Professor of Materials Science and Technology, Full Professor of Advanced “nano-bio” Manufacturing Engineering, Materials Consultant, Panelist and Expert Reviewer for several international leading companies and funding agencies, and Advisory Editor for Elsevier Publications, USA. He has strong contributions to the fields of materials science and engineering with a publication list (+220) includes 17 books for Springer and Elsevier. He won numerous national and international prestigious prizes and awards such as Humboldt Research Award for Experienced Scientists at Max Planck Institute, Germany; Fulbright, NSF, and Dept. of Energy Fellowships, USA; Shoman Award in Engineering Science; State Prize of Egypt in Advanced Science and Technology; and many more. He has a strong record of external research funding through competitive grants, industry grants or consultancies. Coordinated several Int'l projects with USA, France, Germany, KSA and Italy. PI, Co-PI or team leader on several international grants - and NSF, DOE-funded grants. Effective leadership and management at department/college and/ university level. Organizer, head speaker and chair at numerous highly prestigious international conferences. Senior Editor and board member of many international journals. Panelist and Reviewer for the USA NSF, and for the German Academic Exchange Service (DAAD). Member of the European Science Foundation, external reviewer for the “Fast-track promotion to the rank of full professor” at Ghent University, Expert Evaluator and Rapporteur for the EU’s FP7, Expert for the German Aerospace Center, Reviewer for the US Fulbright Commission, and many more. He created and delivered four courses for mechanical and manufacturing engineering master students and effectively supervised and graduated 10 PhD and master’s students, and 3 postdoctoral scientists.

Mariusz Ozimek

CEO, VACCO Sp. z o.o., Poland

Mariusz Ozimek is a graduate of the Wroclaw University of Science and Technology (obtained Ph.D. and MSc degrees) and the University of Economics in Wroclaw (post-graduate studies). For nearly 10 years he worked as a Scientific Researcher at Electrotechnical Institute and International Laboratory of High Magnetic Fields and Low Temperatures of the Polish Academy of Science (now the Institute of Low Temperature and Structural Research PAS). During the scientific career, he led a number of R&D projects in the area of functional thin films, magnetic and absorbing materials, and superconductors. At Electrotechnical Institute he designed and built a vacuum unit for thin films preparation by means of magnetron sputtering technology. Since September 2016 to November 2017 he worked as R&D Team Manager at XTPL S.A. Among his tasks was managing the research on the modification and preparation of glass substrates before nanoprinting. He is a co-author of three patents and owner of the PRINCE2 Foundation, IPMA-D and IBM Corporate Readiness certificates in project management. Since December 2017 he holds the function of the CEO of VACCO Sp. z o.o., a company offering PVD coatings for industrial applications. He also carries on his own consulting business.

Reginald B. Little

Professor , Stillman College, USA

Reginald B. Little is Associate Professor of Chemistry.  He is father of 3 sons.  He enjoys music, tennis and jogging. His first and enduring love on earth is chemistry began at 10 years old.   He finished BS in Chemical Engineering at Ga Tech in 1989, MS in Chemical Engineering LSU in 1992 and PhD in Physical Chemistry in 1999 from Ga Tech.He has contributed many discoveries ranging from first discovery of mechanism of carbon nanotube, graphene and diamond nucleation and growth under novel conditions; the Little Effect; mechanism of high temperature superconductivity, ferromagnetic carbon, and fractional reversibly fissing and fusing of nuclei of nonzero nuclear magnetic moments for novel electronic and nuclear dynamics; superluminosity; connecting quantum to classical mechanics by general theory of relativity; transducing gravity to magnetism; and mechanism for cancer genesis by nonzero nuclear magnetic moments for new magnetic field treatment and cure for cancer.

Fei Yao

Assistant professor, University at Buffalo, USA

Fei Yao received her dual Ph.D. degree in Energy Science from Sungkyunkwan University (SKKU), Korea and in Physics from Ecole Polytechnique, France, in 2013. She received her M.S. degree of Science in Engineering from SKKU in 2010 and her B. S. degree in Electronic Information Engineering from Shandong Normal University, China, in 2007. From 2013 to 2015, she worked as a postdoctoral researcher under the guidance of Prof. Young Hee Lee in Center for Integrated Nanostructure Physics (CINAP), Institute for Basic Science (IBS), Korea. From 2015 to 2017, she worked as a postdoctoral research associate in Electrical Engineering, University of Notre Dame, USA. Currently, she is an Assistant Professor in the Department of Materials Design and Innovation, University at Buffalo. Her research interests include low-dimensional materials synthesis, property engineering, and their applications in electrochemical energy storage and conversion, electrochemical sensors and electronic devices.

About Conference

It is with an immense pleasure and a great honor, we would like to welcome you all at our World Expo on Material Science and Engineering conference during September 18-20, 2019 at Sallés Hotel Ciutat del Prat, Barcelona, Spain

The conference is hosted by Linkin Science. These conferences are well crafted and designed by a team of skilled experts. Our conferences are vast expanded into Medical, life sciences, health care, Engineering and other social sciences. Each conference, summit or executive briefing is tailored to the sector, topic and audience need. Our event structure varies depending on issue and market requirements featuring Keynote presentations, Oral talks, Poster presentations, Young research forum, Exhibitions, roundtables and variable formats. Our mission is to bring the researchers on a common platform and provide opportunity for them to interact. This scientific networking helps for the betterment of science by exchanging the ideas in a broader way. Magnifying Scientific Knowledge by Sharing the research and ideas. We believe in accelerating the possibilities of novel discoveries and enhancement in scientific research, by connecting scientific community for knowledge sharing. Join us to redefine and explore new research, to provide a credible source to barter ideas for scientific studies besides transforming the true outcomes of a distinct scientific discovery and grab the attention for rare emerging technologies.

Importance and Scope:

Materials Science and Materials Engineering are closely related as follows: the former deals with the relationships between the various structures and properties of materials while the latter mainly involves applications of the structure-property correlations in designing or engineering the material with tailored properties.

A variety of Engineering Materials are indispensable for day-to-day life in modern society and used as basic building blocks in different industries. These engineered materials have vitally contributed to numerous technological advancements in various fields as diverse as medicine and health, national security, information technology, aerospace, telecommunications, structural engineering, transportation, agriculture, textiles, plastics, and the environment.

The field of Materials Science and Engineering combines the basic knowledge and the emerging applications thus forming a bridge between the Basic Sciences like Physics, Chemistry and Mathematics and various Engineering disciplines, viz. Aerospace, Chemical, Civil, Computer, Electrical, Electronics and Telecommunication, and Mechanical Engineering.

Scientific Sessions

Material Science and Engineering

Materials Science and Engineering is an acclaimed scientific discipline, expanding in recent decades to surround polymers, ceramics, glass, composite materials and biomaterials. Materials science and Engineering, involves the discovery and design of new materials. Many of the most pressing scientific problems humans currently face are due to the limitations of the materials that are available and, as a result, major breakthroughs in materials science are likely to affect the future of technology significantly.

Novel Materials Synthesis and Fabrication Technologies

Novel materials have major roles in different fields of engineering; they are given by different structures and materials, to our knowledge to the physical and the virtual world. It should be obvious that all matters are made of crystal materials. Metals that carry unique property of pottery, and earthenware production are uniquely in contrast to polymers. The properties of materials depend upon the iotas that are utilized and how they are made together. The nuclear structure of any novel material basically influences the substance's physical, warm, electrical, attractive, and optical properties. Also the micro-structure and macro-structure can influence these properties but they mostly affect the mechanical properties and the rate of concoction response.

Fabrication techniques with focus on trends which are highly relevant for practical applications in the industry in the recent and coming years. Particular emphasis shall be given to the impact of welding and corrosion protection techniques on structural performance, on the development of lighter structures and on computer and IT technologies and tools, which are meant to link design and production tools and to support efficient production.

Materials Technology for 3D Printing Innovation

Materials Technology For 3D Printing Innovation: 3D Material Technologies utilizes Metal Additive Manufacturing / 3D Printing to take design concepts to functional metal components in hand on an accelerated timeline. 3DMT’s primary business is prototyping and short-run production for Aerospace, Defense, Medical and Industrial customers that need the speed to market of additive manufacturing or the design freedom the process allows.

Smart Optical Materials and Device Applications

The increasing requirements of hyperspectral imaging optics, electro/photo-chromic materials, negative refractive index metamaterial optics, and miniaturized optical components from micro-scale to quantum-scale optics have all contributed to new features and advancements in opticstechnology. Development of multifunctional capable optics has pushed the boundaries of optics into new fields that require new disciplines and materials to maximize the potential benefits. The purpose of this study is to understand and show the fundamental materials and fabrication technology for field-controlled spectrally active optics (referred to as smart optics) that are essential for future industrial, scientific, military, and space applications, such as membrane optics, filters, windows for sensors and probes, telescopes, spectroscopes, cameras, light valves, light switches, and flat-panel displays. 

Integrated Nano and Micro- Structures

Nanostructured Materials (NSM) are Advanced materials with a microstructure the trademark length size of which is on the request of a couple (commonly 1–10) nanometers. NSM might be in or far from thermodynamic harmony. Nanostructured Materials combined by supramolecular science are cases of Nanostructured Materials in thermodynamic harmony. Nanostructured Materials comprising of nanometer-sized crystallites (e.g. of Au or NaCl) with various crystallographic introductions or potentially synthetic creations are far from thermodynamic harmony.

Microstructure is the very small scale structure of a material, defined as the structure of a prepared surface of material as revealed by a microscope above 25× magnification. The microstructure of a material (such as metals, polymers, ceramics or composites) can strongly influence physical properties such as strength, toughness, ductility, hardness, corrosion resistance, high/low temperature behaviour or wear resistance. These properties in turn govern the application of these materials in industrial practice.

Advanced Energy Materials

The increasing energy demand due to growing global population and the critical relationship between Energy, environment and sustainability lead to novel discoveries and advancement in the field of Energy Materials in search of alternative resources. The prime requirement to transform feedstock into suitable energy sources is the catalyst for better solar cells and energy storage materials. Energy Materials is making ground breaking developments in the science of materials innovation and production. At present, novel materials are technologically advanced for energy storage and generation. The transformation of Conventional fossil fuel to renewable and sustainable energy sources due to the geophysical and social stress results in the development of Advanced Energy Materials to support emerging technologies. The emerging materials for energy associated application are photovoltaic, fuel cells, nanostructured materials, light sources etc. The international EaaS (Energy as a service market) value is likely to be USD 1,116.5 million in 2018 and is estimated to reach USD 7,336.1 million by 2023 at a growing (CAGR) rate of 45.72% from 2018 to 2023. The foremost drivers are growing energy consumption, price instability and emerging potential of renewable energy resources.

Mining and Metallurgy

The Mining and Mineral Process Engineering option focuses on the aspects of geological, civil, mechanical, electrical, and industrial engineering, together with business and management skills, that are integrated in the challenge of extracting minerals from the Earth. Mining engineers are involved in all stages of the process: from exploring for new mineral deposits and deciding if they can be mined economically, through designing and constructing mines at and below the ground, to managing and operating mines, to preparing raw mineral products for manufacturing or energy industries.  

Metallurgy is a domain of material science and engineering that studies the physical and chemical behavior of metallic elements, their intermetallic compounds and their mixtures which are called as alloys. Outstanding engineering solutions and metallurgical science to support our national security and industry customers a scope that spans all alloys, ceramics, and compounds from uranium to hydrogen, with a strong emphasis on unconventional, low symmetry materials.

Surface Science and Engineering

Surface science is the study of physical and chemical phenomena that occur at the interface of two phases, including solid–liquid interfaces, solid–gas interfaces, solid–vacuum interfaces, and liquid–gas interfaces. It includes the fields of surface chemistry and surface physics. Some related practical applications are classed as surface engineering. The science encompasses concepts such as heterogeneous catalysis, semiconductor device fabrication, fuel cells, self-assembled monolayers, and adhesives. Surface science is closely related to interface and colloid science. Interfacial chemistry and physics are common subjects for both. The methods are different. In addition, interface and colloid science studies macroscopic phenomena that occur in heterogeneous systems due to peculiarities of interfaces.

Biomaterials and Tissue Engineering

Biomaterials are those materials which are usually made of multiple components that interact with biological system. Biomaterials are normally used in medical application like drug delivery, therapeutics, and diagnostics to replace a natural function. The most commonly used biomaterials are polymers. All biomaterials meet certain criteria and regulatory requirements before they can be qualified for use in medical applications. Biomaterial Science has a broad scope that covers the fundamental science of biomaterials through to their biomedical applications. 

Tissue engineering is an emerging field which involves biology, medicine, and engineering that is likely to revolutionize the ways we improve the health and quality of life for millions of people worldwide by restoring, maintaining, or enhancing tissue and organ function. In other words, tissue engineering is the development of artificial tissue and organ systems. The term regenerative medicine is often used synonymously with tissue engineering, although those involved in regenerative medicine place more emphasis on the use of stem cells to produce tissues.

Biophysics and Systems Biology

Physical scientists use mathematics to explain what happens in nature. Life scientists want to understand how biological systems work. These systems include molecules, cells, organisms, and ecosystems that are very complex. Biophysicists work to develop methods to overcome disease, eradicate global hunger, produce renewable energy sources, design cutting-edge technologies, and solve countless scientific mysteries. In short, biophysicists are at the forefront of solving age-old human problems as well as problems of the future.

Systems biology is the computational and mathematical modeling of complex biological systems. It is a biology-based interdisciplinary field of study that focuses on complex interactions within biological systems, using a holistic approach (holism instead of the more traditional reductionism) to biological research.

Optics, Photonics, Electronics And Magnetic Materials

Optical and Electronic smart materials are the materials which are associated with electricity. It incorporates the design, study, and manufacture of smart materials that convert electrical signals into photon signals and vice versa. Any device that operates as an electrical-to-optical or optical-to-electrical is considered as an optoelectronic device. Optoelectronics is built based on the quantum mechanical effects of light on electronic materials, sometimes in the presence of electric fields, especially semiconductors. Optoelectronic technologies comprise of laser systems, remote sensing systems, fiber optic communications, optical information systems, and electric eyes medical diagnostic systems.

Instrumentation Technology

Instrumentation engineering is a branch of electrical and electronic engineering that is concerned with the study of engineering principles and procedures of computing instruments used in designing and assembling automated systems. The work of instrumentation engineers is critical in the industrial manufacturing sector as they are required to construct, design, and maintain instruments and systems of an industry and decide on the type of instruments needed for better quality and efficiency of the products. Instrumentation engineers need to possess creative skills, in addition to technical expertise. They should have the ability to write custom software applications as well as computer programs relating to the proposed objectives. They should also be familiar with operating elementary machinery systems and industrial tools. Owing to rapid industrial and economic growth, job opportunities in this sector are increasing every day.

Polymers Science and Technology

Compound could be an immense molecule or full scale particle made out of collection of relentless subunits known as monomers. The technique for changing monomers in to polymers is named polymer science. They're starches, lipids, proteins and nucleic acids. These polymers are framed absolutely one of a kind monomers and serve various limits. Polymers, though introduced in the materials field in a meaningful manner only very recently, occupy a major place and pivotal position in the materials field today. In performance characteristics and application prospects and diversity, they offer novelty and versatility not found in any other kind of materials.

Composite Materials, Ceramics and Glass

Composite materials are composed with two different materials, which combine to give properties superior to those of the individual constituents. There are many component materials and different processes that can be used make composites extremely versatile and efficient. They typically result in lighter, stronger, more durable solutions compared to traditional materials. The main properties of the materials are Weight reduction, Durability and maintenance, Added functionality, Design freedom. The word Ceramics covers inorganic, nonmetallic, solid materials that have been hardened by baking at a high temperature. The most important of these were the traditional clays, made into pottery, dinnerware, bricks, and tiles. Ceramics have high hardness, high compressive strength, and chemical inertness. Ceramic engineering is the science and technology of creating objects from inorganic, non-metallic materials. The term includes the purification of raw materials, the study and production of the chemical compounds concerned, their formation into components and the study of their structure, composition and properties. Glass is a non-crystalline amorphous solid. It is mainly made of silica; glass is made of silica only is called silica glass. According to the definition of ASTM standards for Glass, "glass is an inorganic product of fusion which has been cooled to a rigid condition without crystallization".

Nanomaterials and Nanotechnology Applications

Nanomaterials (nanocrystalline materials) are substances possessing grain sizes on the order of a billionth of a meter. They manifest extraordinarily charming and beneficial properties, which can be exploited for a ramification of structural and non structural packages. Nanomaterials own unique, beneficial chemical, bodily, and mechanical houses, they may be use for an extensive form of programs, like next era laptop chips, kinetic power (KE) penetrators with more advantageous lethality, better insulation materials, Phosphors for excessive-Defination TV, Low cost Flat-Panel displays, more and more difficult cutting tools, elimination of pollution, excessive strength density, Batteries, excessive power magnets, high sensitive sensors, motors with greater gas efficiency, Aerospace addititives with superior performance characteristics, higher and density weapons platforms, Longer-Lasting Satellites. Longer-Lasting medical implants, Ductile, Machinable ceramics, huge electro chromic show devices.

Industrial Coating Materials

Industrial coatings are products engineered specifically for their protective and functional properties Most industrial coatings are used for corrosion control of concrete and steel, but they lie under a complex market umbrella and work in numerous areas. Also known as Original Equipment Manufacture (OEM) coatings, these industrial-grade products can be used for a number of applications. The most common application for these coating products is to prevent corrosion of steel and concrete. Another common use is to make the material less susceptible to fire or other hazards.

Material Science Applications

Material Science is that the branch of science deals with the structure, properties, performance, characterization and method of materials that related to construction or manufacture like metals, polymers, ceramics and composites etc. Through the help of the material science we'll apprehend the history of the material like physical and chemical properties, so thus a reason material science and engineering options a pleasant scope significantly in rhetorical engineering, Nano technology, bio materials, metallurgy, failure analysis, investigation materials.

Materials Theory, Computation and Design

Computational and theoretical materials science is playing an increasingly important role in advancing the search for novel materials and understanding the properties of existing ones. Modern computational hardware and software enable faculty to create virtual laboratories, where materials are tested and properties predicted computationally.

Nanomedicine and Biomedical Engineering

Nanomedicine can be defined as medical application of nanotechnology. Nanomedicine ranges from the medical applications of nanomaterials and biological devices, Nano electronic devices & biosensors and possible future applications of molecular nanotechnology. Nanomaterials can be functionalised to interface with biological molecules & structures as the size of nanomaterials is comparable to most biological molecules and structures. Nanomaterials can be useful for both in vivo and in vitro biomedical research and applications and integration of nanomaterials with biology has led to the development of advanced diagnostic devices, physical therapy applications, analytical tools, contrast agents and drug delivery vehicles. Nanomedicine strives for delivering valuable set of research tools & clinically useful devices and its industry sales reached $19 billion in 2017, with an average of $3.8 billion investment in nanotechnology R&D every year and increase of 52% per year global funding for emerging nanotechnology.  Biomedical engineering is the application of the principles and problem-solving techniques of engineering to biology and medicine. This is evident throughout healthcare, from diagnosis and analysis to treatment and recovery, and has entered the public conscience though the proliferation of implantable medical devices, such as pacemakers and artificial hips, to more futuristic technologies such as stem cell engineering and the 3-D printing of biological organs.

Smart Materials and Structures

Smart materials also called moreover Intelligent or responsive materials, These materials are having no less than one property that can be basically changed in a controlled way by outside lifts, for instance, extend, temperature, sogginess, pH, electric or appealing fields, light, or blend blends. Brilliant Materials are the commence of various applications, including sensors and actuators, or made muscles, particularly as electrically started polymers.

Energy Storage and Conversion

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.

Materials Chemistry

Materials science incorporates the usage of science for the layout and association of materials with entrancing or possibly significant physical traits, for instance, appealing, optical and essential or synergist properties. It in like manner incorporates the depiction, taking care of and nuclear level understanding of these substances.

Scientific Sessions

Abstract Submission : Closed

Final Round Registration : Closed

  • Material Science and Engineering
  • Novel Materials Synthesis and Fabrication Technologies
  • Materials Technology for 3D Printing Innovation
  • Smart Optical Materials and Device Applications
  • Integrated Nano and Micro- Structures
  • Advanced Energy Materials
  • Mining and Metallurgy
  • Surface Science and Engineering
  • Biomaterials and Tissue Engineering
  • Biophysics and Systems Biology
  • Optics, Photonics, Electronics And Magnetic Materials
  • Instrumentation Technology
  • Polymers Science and Technology
  • Composite Materials, Ceramics and Glass
  • Nanomaterials and Nanotechnology Applications
  • Industrial Coating Materials
  • Material Science Applications
  • Materials Theory, Computation and Design
  • Nanomedicine and Biomedical Engineering
  • Smart Materials and Structures
  • Energy Storage and Conversion
  • Materials Chemistry
  • Materials, Mechatronics and Manufacturing

Registration Categories

Abstract Submission : Closed

Final Round Registration : Closed



World Expo on Material Science and Engineering conference anticipates being able to provide funding to assist some attendees coming from Lower and Middle Income Countries to present their science at the summit.  Participants desiring to be considered for one of these awards need to specify their interest after their submission of the required abstract. Selected participants will receive a cash award of $250 to $1,000 (USD) scholarship Under the 3 categories

  1. Outstanding Submitted Abstract
  2. Best Research of the conference as evaluated by the Scientific Committee
  3. Young Researcher Award under YRF category to encourage budding scientists/researcher.

Decisions will be made based on evaluation of the submitted abstract by the Scientific Committee and amount of funds available. The decision made by the Scientific Committee would be final. We want you to grab this opportunity and participate in the conference...!

Conference Venue

Sallés Hotel Ciutat del Prat, Barcelona, Spain

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