Online Event

22nd International Conference on

Advanced & Energy Materials

Theme: Insight into the most recent energy materials developments

Event Date & Time

Event Location

Brochure Program Abstract Registration ReaderBase Awards

20 Years Of Excellence in Scientific Events

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RENOWNED/PREVIOUS SPEAKERS

Conference Speaker

GENDA CHEN

Missouri University of Science and Technology
USA

Conference Speaker

VLADIMIR LEVCHENKO

Lomonosov Moscow State University
Russia

Conference Speaker

VOJISLAV V.MITIC

University of Nis
Serbia

Conference Speaker

AMAN ULLAH

University of Alberta
Canada

Conference Speaker

JOHN OWEN ROBERTS

Freelance and former Open University Tutor
UK

Conference Speaker

TSVETANKA S ZHELEVA

US Army Research Lab
USA

Conference Speaker

SATOSHI FUJII

National Institute of Technology
Japan

Conference Speaker

HIROYUKI AOKI

Japan Atomic Energy Agency
Japan

Conference Speaker

EUNSOO CHOI

Hongik University
South Korea

Conference Speaker

Shou-Heng Liu

National Cheng Kung University ta
Taiwan

Conference Speaker

Atissun Kittilaksanon

The Petroleum and Petrochemical College
Thailand

Conference Speaker

J.R. Rodriguez-Sanchez

Facultad de Ciencias Quimicas UAdeC
Mexico

Tracks & Key Topics

Energy Materials 2023

About Conference

Euroscicon invites participants from all over the globe to take part in this annual flagship conference with the theme "Insight into the most recent energy materials developments" The thought behind Energy Materials 2023 is to share the new ideas among the professionals, industrialists, and students from the research areas of Materials Science, Nanotechnology, chemistry, and Physics to share their research experiences, interactive discussions, and technical sessions at the event. This event would be the perfect platform for companies and institutions to present their services, products, innovations, and research results.

Advanced Materials is an intense subject to study and learn about Energy Materials. Through technological innovation and advancements in the study of Energy Materials, it has provoked and contributed to the emergence of various materials such as nanomaterial’s, biomaterials, electronic, optical, magnetic, fuel cells, polymers, Solar Energy materials, smart materials, semiconductor materials, and the design of complex structures.

EuroSciCon, the 22nd European Annual Conference on Energy Materials, will be the largest materials conference, providing a top scientific venue for reporting and learning about the latest research and development, as well as debating new applications and technologies. This event features the latest technology from around the world as well as professional networking with industries, leading working groups, and panels.

Meet the Target Business Sector: With people from all over the world interested in learning about Energy Materials, this is the ideal opportunity to meet the largest group of people from all over the world. This conference will allow you to spread information, meet with currents, sprinkle with another product offering, and gain name recognition on this occasion. This symposium features widely respected speakers, cutting-edge methodologies and strategies, and the most recent advancements in Materials science and engineering.

Who can attend??

Energy Materials 2023 brings together experts from various fields to explore the future of Advanced Energy Materials as well as the importance of Energy materials and engineering in today's environment. The conference will bring together directors, Energy scientists, directors of Laboratories, Universities, Industries, Professors, Delegates, research specialists, Post-Doctoral Fellows, researchers, students, research companies, Market Research firms, and all other interested participants eager to improve and update their knowledge of Advanced and Energy Materials.

Why to attend?

Energy Materials 2023 offers a fantastic opportunity to meet and make new contacts in the field of Materials Science and engineering by providing collaboration spaces and break-out rooms with tea and lunch for delegates between sessions, providing invaluable networking time for you. It allows delegates to have issues in materials science addressed by recognized global experts who are up-to-date with the latest developments in the field and provide information on new techniques and technologies. This International Energy Materials Conference will feature world-renowned keynote speakers, plenary speeches, a young research forum, poster presentations, technical workshops, and career guidance sessions.

Target Audience

  • Materials Scientists and Research Professors
  • Physicists/Chemists
  • Junior and senior research fellows in Materials science, nanotechnology, Polymer science,
  • Biotechnology
  • Materials Science Students
  • Directors of chemical companies
  • Materials Engineers
  • Members of different Materials science associations
  • Polymer companies

The joy of attending Energy Materials 2023 brings with it improvement and incremental growth in approaching innovative research from a broader perspective and the beauty of living in international diversity.

Come and be a part of it...!

Young Researchers Forum - Young Scientist Energy Materials-2023

Young Research’s Awards at Energy Materials-2023 for the Nomination: Young Researcher Forum - Outstanding Masters/Ph.D./Post Doctorate thesis work Presentation, only 25 presentations acceptable at the Energy Materials-2023 young research forum.

Benefits:

  • Young Scientist Award recognition certificate and memento to the winners
  • Our conferences provide the best Platform for your research through oral presentations.
  • Learn about career improvement with all the latest technologies through networking.
  • Through this forum, young scientists will get appropriate and timely information.
  • A platform for collaboration among young researchers for better development.
  • Provide an opportunity for research interaction with established senior investigators across the globe in the field.
  • Share the ideas with both eminent researchers and mentors.
  • It’s a great privilege for young researchers to learn about the research areas and expand their research knowledge.

Opportunities for Conference Attendees:

For Researchers & Faculty:

  • Speaker Presentations
  • Poster Display
  • Symposium hosting
  • Workshop organizing

For Universities, Associations & Societies:

  • Association Partnering
  • Collaboration proposals
  • Academic Partnering
  • Group Participation

For Students & Research Scholars:

  • Poster Competition (Winner will get Best Poster Award)
  • Young Researcher Forum (YRF Award to the best presenter)
  • Student Attendee
  • Group Registrations

For Business Delegates:

  • Speaker Presentations
  • Audience participation
  • Symposium hosting
  • Book Launch event
  • Networking opportunities

For Companies:

  • Exhibitor and Vendor Booths
  • Sponsorships opportunities
  • Product launch
  • Workshop organizing
  • Scientific Partnering  
  • Marketing and Networking with clients

Conference Topics

Energy materials

Modelling and simulation in Energy materials

Fuel cells

Thin Films and Surface Science

Concentrating Solar Power Materials and Systems

Sustainable Energy Materials Conversion

3D Microstructural Characterization of Materials

Advanced Graphene Materials

Hydrogen Energy

Crystalline Porous Materials

Catalysis and Energy Materials

Polymer Energy Materials

Advanced Nano materials

Biomaterials for Energy Production

Emerging Technologies for Energy Applications

Energy Harvesting Materials

Batteries and Energy Storage

Nuclear Materials and Energy

Geothermal Energy

Electrochemical energy conversion

Automotive Technologies and Fuel Economy

Systems Dynamics & Sustainable Energy

Smart Power Grids

Fossil Energy

Solidification of Energy Materials

About Subject:

Energy Materials is a field of technology that encompasses the spectrum of material types and how to use them in manufacturing. Materials span the range: metals, Energy, polymers (plastics), semiconductors, and combinations of materials called composites. We live in a world that is both dependent on and limited by materials. Everything we see and use is made of materials: cars, airplanes, computers, refrigerators, microwave ovens, TVs, dishes, athletic equipment of all types, and even biomedical devices such as replacement joints and limbs. All of these require materials specifically tailored for their application. Specific properties are required that result from carefully selecting the materials and controlling the manufacturing processes used to convert the basic materials into the final engineered product.

Energy materials have always been with us since ancient times, serving as the foundation for human evolution and development. Materials scientists place a premium on knowing how a material's history affects its structure and, consequently, its qualities and performance. All of these variables have significantly contributed to the development of human life quality. Energy Materials provides an in-depth overview of materials research and expands your creativity with new definitions. Energy Materials 2023 provides the foundation for you to construct your own castle of knowledge, preparing you for the challenges of the energy science industry.

 

 

Sessions & Tracks

Track 1: Energy Materials:

It is a companion assessed logical diary encompassing vitality-related research, for example, photovoltaic, batteries, super capacitors, energy components, hydrogen advancements, thermo-electrics, photo-catalysis, solar power innovations, appealing refrigeration, and piezoelectric materials. It sends out welcoming surveys and advance reports, as well as comprehensive papers and fast correspondences.

Track 2: Fuel Cells:

An electrochemical cell converts the compound liveliness of a fuel into electricity via an electrochemical reaction of hydrogen fuel with oxygen or another oxidizing agent. Power modules differ from batteries in that they require a continuous source of fuel and oxygen (usually from air) to support the compound reaction, but in a battery, the substance vitality originates from synthetic concoctions that are effectively present in the battery. Energy components can provide power indefinitely as long as fuel and oxygen are available.

Track 3: Modelling and simulation in Energy materials:

The journal examines the properties, structure, and direction of all sorts of materials at scales ranging from the atomic to the apparent. This consolidates the electronic structure and properties of materials managed by stomach muscle initio, as well as semi-correct strategies, atomic-level material properties, microstructural-level marvels, continuum-level exhibiting identifying with material lead, and demonstrating conduct in advantage. Material qualities such as mechanical, microstructural, electrical, mixture, natural, and optical properties are also of interest.

Track 4: Thin Films and Surface Science:

Surface science is critical for understanding materials' electrical, chemical, and mechanical characteristics. Thin film declaration, plasma surface polymerization, and compound covering can all be used to efficiently modify the surface of materials. Surface features can be visualized via x-shaft photoelectron spectroscopy (XPS), Fourier-change infrared spectroscopy (FTIR), Raman scattering, x-pillar reflectivity, ellipsometry, and assistant molecule mass spectroscopy (SIMS).

Track 5: Concentrating Solar Power Materials and Systems:

Concentrated sun-arranged power (also known as concentrating sun-fuelled power, concentrated sun-controlled warmth, and CSP) structures generate solar energy by projecting a large zone of sunlight, or daylight-based warmth, over a small area using mirrors or central foci. When focused light is converted to heat, it powers a glow engine (often a steam turbine) linked to an electrical power generation or induces a thermochemical process.

Track 6: Sustainable Energy Materials Conversion:

The ever-increasing human population and the burgeoning global economy have resulted in increased vitality usage and the understanding that non-renewable energy sources are a finite resource on the planet. More crucially, due of the rising global temperature, CO2 emissions must be reduced in order to minimize or avoid supporting global warming. The two requirements have fuelled global efforts to transform the ebb and flow vitality supply method into an economy based on sustainable power sources such as solar, wind, biomass, geothermal, and water-based power. As a result, these variables have fuelled the increased and consistently growing enthusiasm for the domains of vitality collecting and capacity observed in the preceding two decades.

Track 7: 3D Microstructural Characterization of Materials:

The concept of microstructure can be seen in macrostructural elements. Electrified steel, such as that used in the packing of a light post or a traffic barrier, has a non-consistently hued weave of interlocking polygons in varying colors of dark or silver. Each polygon is a single jewel of zinc clinging to the surface of the steel beneath. Zinc and lead are two common metals that are used to frame large jewels (grains) that are visible to the human eye. Each grain's molecules are classified into one of seven three-dimensional stacking plans or precious stone cross sections (cubic, tetrahedral, hexagonal, monoclinic, triclinic, rhombohedral, and orthorhombic). The arrangement of the frameworks differs across adjacent gems, causing a variation in the reflectivity of each displayed face of the interlocked grains on the agitated surface.

Track 8: Advanced Graphene Materials:

Graphene is a single nuclear layer of graphite, a solid material that is an allotrope of carbon made up of tightly packed carbon iotas arranged in a hexagonal cross section. Graphene's sp2 hybridization and low nuclear thickness distinguish it. These qualities enable graphene to shatter numerous records in terms of quality, power, and heat conduction. This book compiles useful information regarding graphene's numerous advanced applications.

Track 9: Hydrogen Energy:

Hydrogen is the most limitless. Hydrogen gas has notable properties, such as being vapid, bland, and undetectable, which make it highly sought after. It can also be converted into an infinite, non-polluting, zero-emission energy source. It is regarded as the foundation of the new vitality economy.

Track 10: Crystalline Porous Materials:

Crystalline permeable materials are a developing research area in the realm of proton-directing materials that include coordination polymers (CPs), polyoxometalates (POMs), covalent natural systems (COFs), and metal-natural structures (MOFs). Among them are two notable groups that are improving and developing crystalline permeable materials: covalent-natural systems (COFs) and metal-natural structures (MOFs). These materials are distinguished by their extraordinary porosity, dazzling auxiliary thickness, and flexible utilitarian validity at the subatomic level, which finds application in batteries, supercapacitors, and electrochemical vitality storing gadgets. The crystallinity of materials provides soundness for electrochemical treatment, while porosity (high surface zone) aids in the distribution of electrolytes and particle flexibility.

Track 11: Catalysis and Energy Materials:

Catalysis is one of the most significant advances in modern scientific and vitality industries, and it accounts for more than 60% of the concoction amalgamation process. A synergist material is one that can alter and improve response energy or selectivity. Synergist material advancement is a game-changing force for squandering new vitality, treating and controlling contamination, and combining fine synthetic substances and medicines. In situ perceptions of and investigations into the system of reactions among reactants and stimuli at the subatomic or nuclear level are the fundamental starting points for the development of a new age of profoundly viable, vitality sparing, and earth-neighbourly synergist materials.

Track 12: Polymer Energy Materials:

Polymeric materials will be critical in the development of future electronic devices and flexible electronic applications. The investigation of the electrical, basic and concoction properties of polymeric materials is widely used in the applications of microelectronics and low-effort sun-oriented materials. Lithium-particle polymer batteries (LiPo), electrodynamic polymers, polymeric surfaces, polymer crystallization, cationic and plasma polymerization, polymer brushes, and other uses are examples. Polymer-based self-repairing materials have recently been manufactured for vitality collection and capacity. Nanogenerators, Photovoltaics, solar cells, supercapacitors, and lithium batteries are among the self-repairing Energy Harvesting Devices. Lightweight composite material is increasingly being used for vitality storage in adaptable hardware, electric automobiles, and aviation applications.

Track 13: Advanced Nanomaterials:

Nanotechnology is only a method for producing more stable and lighter hockey sticks, bicycles, tennis rackets, play clubs, and other sporting equipment. However, nanotechnology promises to accomplish much more. A more logical conclusion is that it will effectively contaminate every aspect of life and that it must be widely adopted by 2020. Particularly in industry, pharmaceuticals, new registration regimes, and supportability, mass applications are likely to have a huge impact. Here are seven fundamental patterns to look for; some are connected, all are natural, and they all quicken.

Track 14: BioMaterials for Energy Production:

With expanding vitality requests, the world's vitality supply is probably going to drop soon because of the declining non-renewable energy source feed stocks, so science and innovation need to discover elective assets for the creation of energizes. Right now, biomass and sustenance squander are considered sustainable feedstocks for the generation of synthetic concoctions and powers in Europe. These sustainable materials are used for the creation of biopolymers, bioplastics, and bioethanol. Biomolecules, for example, peptides and proteins, are under research to make new Nanomaterials to improve the proficiency of photovoltaic, for example, sun-based cells, and other electronic gadgets. Bioprotein power can likewise be used for non-natural material applications. Biomaterials have likewise been utilized as anode materials in battery-powered lithium batteries. The nanostructure of these materials enhances their electrochemical action, which improves battery execution.

Track 15: Emerging Technologies for Energy Applications:

The expanding power utilization in creating districts improves the power framework and raises concerns with respect to the utilization of sustainable power supplies. Administrations worldwide are progressively putting resources into sustainable power sources, for example, solar and wind. The real players in the power gadgets advertised are Texas Instruments in the US, On Semiconductor in the US, Infineon Technologies in Germany, ST Microelectronics in Switzerland, NXP Semiconductors in the Netherlands, Vishay Inter-innovation in the US, Maxim Integrated Products in the US, and so forth. The real zones for developing advances are Storage, Smart matrix, and electricity. Rising Energy stockpiling incorporates novel, practical methods for putting away vitality, such as enhanced batteries, power modules, hydrogen vitality stockpiling, and transport. Brilliant network innovations empower productive age and utilization of vitality. The rising electricity age is described by innovation to create control from unused assets.

Track 16: Energy Harvesting Materials:

The exploration of vitality gathering materials is encountering extraordinary development and drawing in tremendous intrigue. Abusing as of late procured bits of knowledge into the crucial instruments and standards of photosynthesis, it is currently conceivable to fashion totally new and unmistakable sub-atomic materials and devise counterfeit photosystems and applications far from regular sun-powered cell innovation. In this far-reaching treatment of vitality reaping, a group of universally acclaimed researchers at the front lines of the subject paint a state-of-the craftsmanship picture of present-day vitality collecting materials science. Covering all parts of the subject, going from regular plant and bacterial photosystems through their naturally motivated manufactured analogs to other photoactive sub-atomic materials, for example, dendrimers, the book additionally sets up the hypothesis and hidden standards over the full scope of light collecting frameworks.

Track 17: Batteries and Energy Storage:

The infiltration of sustainable sources (especially twist control) into the power framework has been expanding in the past few years. Accordingly, there have been serious worries over the solid and acceptable activity of the power frameworks. One of the arrangements being proposed to enhance the unwavering quality and execution of these frameworks is to coordinate vitality stockpiling gadgets into the power framework organization. Further, in the present deregulated markets, these capacity gadgets could likewise be utilized to build the overall revenues of wind farm proprietors and even give arbitrage. This paper talks about the present status of battery vitality stockpiling innovations and techniques for evaluating their monetary feasibility and effect on the power framework task. Further, an exchange on the job of battery stockpiling frameworks of electric cross-breed vehicles in power framework stockpiling advancements had been made.

Track 18: Nuclear Materials and Energy:

Atomic vitality originates from part iotas in a reactor to warm water into steam, turn a turbine, and produce power. Ninety-eight atomic reactors in 30 states produce almost 20 percent of the country's power, all without carbon emissions since reactors utilize uranium, not petroleum products. These plants are dependably on: they work all around to dodge intrusions and to withstand extraordinary climates, supporting the framework day in and day out. The advantages of atomic vitality stretch a long way past the sun's carbon power as well. Atomic forces space investigation, disinfects medicinal gear, gives consumable water through desalination, supplies radioisotopes for malignancy treatment, and substantially more. The progression in petroleum derivative costs has set off a restoration of enthusiasm for atomic vitality. This center investigates where we remain with atomic innovation and what materials are expected to acknowledge cutting-edge atomic reactors.

Track 19: Geothermal Energy:

Geothermal vitality is sustainable, clean power that comes from the warm vitality in the underground earth. The world's warm vitality is made by the rot of radioactive components in the earth, along with the warmth from the sun and that remaining from the world's creation. Not at all like sun-powered power or wind control, isn’t geothermal vitality hindered by respite times. The innovation likewise has a little carbon impression being developed. The warmth from geothermal vitality can be (and is) utilized either specifically to warm homes and organizations or in connection with geothermal warmth pumps. In a more smoking condition, or at a more blazing season, water circled through a geothermal circle conveys warm water underneath the world's surface, where it is consumed into the ground; the cooled water is conveyed back up to manage the higher surrounding temperature. Geothermal warmth pumps are one of the ecologically inviting strategies used to cool green server farms.

Track 20: Electrochemical energy conversion:

Electrochemical gadgets, for example, power modules, electrolysers, and batteries, demonstrate incredible guarantees for huge-scale vitality change and capacity applications. Put away electrochemical vitality can possibly cross over any barrier between power-free market activity that emerges with discontinuous sustainable power source age innovations, for example, sun-powered and wind-controlled.

Track 21: Automotive Technologies and Fuel Economy:

One of the main approaches to diminishing transport-related vitality utilization is to decrease fuel utilization rates of engine vehicles (normally estimated in liters of fuel per 100 km). Since 2004, China has executed arrangements to enhance vehicle advancements and lower the fuel utilization rates of individual vehicles. Approach assessment requires exact and satisfactory data on vehicle fuel utilization rates. Be that as it may, such data, particularly for Chinese vehicles under true working conditions, is once in a while accessible from authoritative sources in China. For every vehicle composition, we first survey the vehicle advances and mileage strategies at present set up in China and their effects. At that point, we infer genuine world (or on-street) fuel utilization rates based on data gathered from different sources.

Track 22: Systems Dynamics and Sustainable Energy:

Unmistakably sustainable power sources assume an essential role in accomplishing a decrease in ozone-harming substance discharges. Specifically, we will give careful consideration to the impact of a decrease in the offer of fossil vitality and of a change in the proficiency of the fossil vitality utilized. A framework of elements is displayed in view of a relationship, which is a variety of the Kaya character, and on a GDP that relies upon sustainable power sources, which presents a criticism system in the model. The principle end is that it is conceivable to control the CO2 discharges even under a situation of ceaseless increment of the GDP in the event that it is joined with an expansion of the utilization of sustainable power sources, with a change of the beneficial sectorial structure, and with the utilization of a more productive petroleum product innovation.

Track 23: Smart Power Grids:

The present power organization, outlined by age-old criteria, is appropriate for a unidirectional stream of vitality: from concentrated power generators to aloof utilization. The dissemination of circulated age sources, regularly from profoundly sustainable sources, requires an extreme change in the administration of the power appropriation organization, which needs to end up progressively keen and versatile.

Track 24: Fossil Energy:

Fossil vitality sources, including oil, coal, and petroleum gas, are non-sustainable assets that formed when ancient plants and creatures kicked the bucket and were continuously covered by layers of shake. Over a great many years, distinctive sorts of non-renewable energy sources shaped, relying upon what blend of natural issues was available, to what extent it was covered, and what temperature and weight conditions existed as time passed. Petroleum derivative ventures penetrate or dig for these vitality sources, consume them to create power, or refine them for use as fuel for warming or transportation. In the course of recent years, about three-fourths of human-caused discharges originated from the copying of non-renewable energy sources.

Track 25: Solidification of Energy Materials:

During the time spent on stage change, the fluid stage is utilized as two different ways of warmth trade: unadulterated warmth conduction and common convection, and we abuse CFD programming to complete numerical reproduction. To think about and break down under softening and hardening, the extent of strong and fluid, the season of stage change, the interface of stage change, and the movement temperature picture of fluid locale. To test the impact of characteristic convection under the warmth exchange from stage change and the effect of control by warming and cooling conditions and it was checked by trials.

Track 26: Carbon Nanostructure and Grapheme

Carbon is unequivocally associated with practically all that we administer on a standard timetable. Because of its exceptional properties, for example, high strength at trademark conditions, contrasting hybridizations, a solid covalent bond game plan, and direct mix improvement, carbon has been a point of steady enthusiasm for a few regions. A nanostructure is a structure of medium size among minute and atomic structures. Non-structural detail is microstructure at the nanoscale.

Graphene is an allotrope of carbon in a two-dimensional, nuclear-scale hexagonal cross-section in which one molecule shapes every vertex. It is the essential aid section of different allotropes, including graphite, charcoal, carbon nanotubes, and fullerenes. It can additionally be considered an uncertainly huge sweet-smelling atom, an indisputable event of the social affair of level polycyclic fragrant hydrocarbons.

Track 27: Electronics and magnet materials

This degree fuses the associations that exist between the presentation of electrical, optical, and alluring devices and the microstructural characteristics of the materials from which they are created. Contraption uses of physical wonders are considered, including electrical conductivity and doping, transistors, photo detectors, photovoltaic, brilliance, light-delivering diodes, lasers, optical marvels, photonics, ferromagnetism, and magneto resistance.

Electronic materials are materials that join semiconductors, dielectrics, ferroelectrics, half metals, and superconductors. Warwick research fuses epitaxial advancement of an extent of electronic materials, production of devices from the materials, and presentation of their usefulness for applications in restorative administrations, the low-carbon economy, and information taking care of.

Track 28: Solar Energy Materials

Since a decade ago, the developing potential power age has been sunlight-based innovation. The proliferation of research on materials science and innovation related to photo thermal, photo electrochemical, photovoltaic, and sun-powered vitality transformation is anticipated to be driven by Solar Energy Materials and Solar cells. Sun-oriented safeguard gadgets, radiative cooling frameworks, and heat stockpiling materials are a portion of the photo thermal gadgets. Photochemical and photo electrochemical gadgets incorporate photo catalysis, photo electrodes, a sun-based desalination framework, photo conversion, and their applications. Light-catching, sun-based concentrators, imaging and non-imaging optical authorities, and finishing are the optical properties of materials.

Track 29: Advanced Rubber Materials

Elastic effects the habits where associations and OEMs work. Extraordinarily framed, versatile materials fill a variety of requirements and can routinely mean the difference between life and death. Flexible respiratory security cover, for instance, ought to be made 100% to points of interest and be non-imperfect to fittingly work and withstand prologue to perilous engineered inventions and airborne contaminants.

 

 

Market Analysis

SUMMARY:  Energy Materials 2023 provides a platform for all researchers, scientists, professors, engineers, and CEOs of organizations working in the fields of energy materials and materials science to discuss their research findings and engage in insightful discussions on a variety of energy-related topics, such as solar energy, hydrogen energy, carbon materials, batteries, and power modules. Join us for two thoughtful and engaging lengthy discussions on current energy research materials.

The market is expected to reach 8,230.0 kilotons by 2023. This research discusses two separate types of cutting-edge practical composites. Metal lattice composites and fibre-fortified polymers are examples. Depending on the fortifying instrument, advanced practical composite materials can be classified into three types. These categories are scattering-enhanced, molecule-enhanced, and fiber-enhanced. Asia-Pacific is the fastest-growing business sector for cutting-edge practical composites, with a CAGR of 9.2%. Cars, maritime, energy, aviation, channels and tanks, electrical and gadgets, and consumer durables are all major applications for cutting-edge functional composites.

IMPORTANCE AND SCOPE:  This up-and-coming age of smart materials shows versatile capacities and changes their physical properties, for example, shape, firmness, and thickness, in a predetermined way. Energy Materials have various functionalities, for example, self-versatility, self-detecting, self-mending, and memory, which enable them to be utilized in an assortment of ways.

According to the discoveries, Phase Change Materials (PCMs) comprise the quickest-developing material sort, with a vigorous 20% CAGR in the worldwide market for Smart Materials. The expanding use of basic items in applications, for example, building assets, gadget cooling, vitality stockpiling, delivering, and bundling, would additionally drive interest in these materials. Piezoelectric Materials corner the biggest offer of the worldwide Smart Materials showcase, representing a conjectured 66% offer in 2022.

 

Past Conference

The 21st European Annual Conference on Advance and Energy Materials (ADVANCED MATERIALS 2020), hosted through EuroSciCon, took place at the IP CITY Hotel in Osaka, Japan, all through October 7–8, 2020. It was once organized via EuroSciCon, and generous responses used to be obtained from the Editorial Board Members of EuroSciCon Journals as well as from eminent scientists, gifted researchers, and the young scholar community. Researchers and students who attended from one-of-a kind parts of the world made the convention one of the most successful and productive activities in 2020 at EuroSciCon. The two-day application witnessed a thought-provoking keynote and plenary.

Presentations from professionals in the subject of Structural and Engineering Research, highlighting the theme "Exploring innovations in the field of Materials Technology and Energy Science"

The meeting used to be carried out through a number of sessions, in which discussions were held on the following major scientific tracks:

  • Advanced Nanomaterials
  • Energy Harvesting Materials
  • Advanced Energy Materials
  • Giothermal Energy
  • Hydrogen Energy
  • Nuclear Materials and Energy
  • Biomaterials for Energy Production
  • Fuel Cells
  • Solidification of Energy Materials
  • Smart Power Grids
  • Crystalline Porous Materials
  • Thin Films and Surface Science
  • Advanced Rubber Materials
  • Advanced Graphene Materials

The highlights of the meeting were the eminent keynote lectures by:

The Advance Material 2020 Conference performed a vital role in promoting multidisciplinary interactions between Advance and Energy Material Research to enhance lookup in Advance and Smart Material Engineering.

We would like to mainly thank our Moderator for his contribution to the conference.

We definitely thank the Organizing Committee Members and the Editorial Board of the Advance Material 2020 Conference for their gracious presence and continuous aid for the duration of this event. With the precious feedback and beneficent response obtained from the contributors of the event, EuroSciCon would like to announce the commencement of the "22nd International Conference on Advanced and Energy Materials" at some stage in December 18–19, 2023, through online or webinar with the theme "Insight into the most recent energy materials developments".

Let us meet once more at Energy Materials 2023.

 

 

Learn More

Energy Materials Universities in USA:

Massachusetts Institute of Technology | Northwestern University (McCormick) | Stanford University | University of California--Santa Barbara | University of Illinois--Urbana-Champaign | University of California—Berkeley | Georgia Institute of Technology | California Institute of Technology | Cornell University | University of Michigan--Ann Arbor | Pennsylvania State University-University Park | Carnegie Mellon University | Air Force Institute of Technology | Alfred University--New York State College of Ceramics (Inamori) | Arizona State University (Fulton) | Auburn University (Ginn) | Binghamton University--SUNY (Watson) | Boise State University | Boston University | Brown University | Case Western Reserve University | Clarkson University | Clemson University | Colorado School of Mines | Columbia University (Fu Foundation) | Dartmouth College (Thayer) | Drexel University | Duke University (Pratt) | Florida A&M University - Florida State University | Florida International University | Harvard University

Energy Materials Universities in Asia:

Nanyang Technological University, Singapore (NTU) | National University of Singapore (NUS) | KAIST - Korea Advanced Institute of Science & Technology | Peking University | Seoul National University | The Hong Kong University of Science and Technology| Shanghai Jiao Tong University | Pohang University of Science And Technology (POSTECH) | National Taiwan University (NTU) | University of Science and Technology of China | Sungkyunkwan University (SKKU) | Beijing Institute of Technology | Harbin Institute of Technology | Indian Institute of Science | Indian Institute of Technology Bombay (IITB)

Energy Materials Universities in Europe:

University of Cambridge | University of Oxford | University of Oxford | RWTH Aachen University | The University of Manchester | Institut polytechnique de Grenoble - Grenoble Institute of Technology  | KIT, Karlsruhe Institute of Technology | Technische Universität Dresden | Technical University of Munich | The University of Sheffield | University of Birmingham | Ecole Polytechnique | Ludwig-Maximilians-Universität München | University of Nottingham | University of Bristol | University of Leeds |

Advanced Materials Companies in USA:

Matterport | BASF | Formlabs | NEC | NatureWorks | Zymergen  | Dow Chemicals | Twist Bioscience | Kebony | Oxford Nanopore | TechStars | GaN Systems | Desktop Metal | Bolt Threads | LanzaTech | Modern Meadow | SCHRODINGER, INC. | Soft Robotics | DuPont Industrial | Applied Materials, Inc. | GreenRoad | Azavea Inc | Sunfire | KLA-Tencor Corporation

Advanced Materials Companies in Europe:

Mighty Buildings | Mighty Buildings | Reaction Engines | Geltor | Lygos | Matmatch | Industrial Microbes | CustoMem | CustoMem | Citrine Informatics | Lingrove | Ras Labs | Ras Labs | Innova Dynamics | Innova Dynamics | BeAble Capital | Zenogen | Prometheus Initiative | NANOGAP | EcoMachines Ventures | Embark Ventures | Boundary Impact Ventures | CLEAN COPPER SUPPLY CHAIN ALLIANCE, pbc | PLUSfoam | novoMOF

 

 

Media Partners/Collaborator

A huge thanks to all our amazing partners. We couldn’t have a conference without you!

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Sponsors/Exhibitors

A huge thanks to all our amazing partners. We couldn’t have a conference without you!