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Advanced Energy Materials 2023, Germany

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Advanced Energy Materials 2023

About Conference

With the splendid success of Advanced Energy Materials 2022, we are pleased to announce and invite you all for the upcoming 25^th International Conference on Advanced Energy Materials and Research” (Advanced Energy Materials 2023) with the theme "Exploring the Challenges and opportunities in the Emerging Market of Energy materials" which is going to be held during May 24-25, 2023 in Berlin, Germany.

Advanced Energy Materials 2023 provides platform for world-wide Researchers, Scientists, Professors, Engineers, and CEO’s of Energy Materials and Materials Science companies to share their research experience and indulge in interactive discussions on all aspects of Energy Materials, Solar Energy, Hydrogen Energy, Carbon Materials, Batteries and fuel cells. Join us for two intensive and interesting days of discussion on contemporary Energy Materials research.

Young Researchers Forum - Young Scientist Awards

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

Young Scientist Benefits

Our conferences provide best Platform for your research through oral presentations.
Share the ideas with both eminent researchers and mentors.
Young Scientist Award reorganization certificate and memento to the winners
Young Scientists will get appropriate and timely information by this Forum.
Platform for collaboration among young researchers for better development
Award should motivate participants to strive to realize their full potential which could in turn be beneficial to the field as whole.

Important and Scope

Energy is a part of science in which materials technology plays an important role as Advanced Energy Materials to meet the needs of future environment. The increasing ecological problems such as energy storage, generation and conservation are the major drivers of Energy Materials technology. There is a need of developing sustainable energy production and consumption to achieve the socio economic and environmental targets.

The major significance of Energy helps in strengthening the research and advancement of materials for energy applications. The universal emphasis on energy is to develop materials for energy generation, low energy processing, energy conservation and conversion to meet the increasing energy demand of the country.

Advanced Energy Materials provides wide range of sessions that discourse the current innovations and novel approaches for the expansion of energy materials to meet the global desires. Advanced Energy Materials 2023 covers major subjects such as fuel cells, organic and inorganic photovoltaic, batteries and super capacitors, Piezoelectronics, hydrogen generation and storage, thermoelectric, photo catalysis, solar fuels and thermosolor power.

Why to attend?

Advanced Energy Materials 2023 offers an eccentric chance to meet and make new-fangled interactions in the field of Energy Materials, Materials Science and Engineering, by providing collaboration and break-out between sessions with valuable networking time. It aids delegates to have novel ideas, addressed on Energy Materials and Materials Science by renowned international professionals who are up to date with the progresses in Energy Materials and Materials Science field. This Global Advanced Energy Materials Conference assert knowledge with world prominent plenary speeches, keynote speakers, Young research forum, poster presentations, technical workshops and exhibitions

Target Audience

Energy Materials Scientists/ Researchers
Materials Scientists/Research Professors
Physicists/Chemists
Junior/Senior research fellows of Energy Materials/ Materials Science/ Nanotechnology
Energy Materials and Materials Science Students
Directors of chemical companies
Materials Engineers
Members of different Materials science associations.
Polymer Companies
Graphene Societies and Association

Scientific Sessions

Track 1: 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

Advanced Energy Materials Societies & Associations

Europe: Federation of European Materials Societies, Austrian Society for Metallurgy and Materials, The European Semiconductor Industry Association (ESIA), European Materials Research Society, Spanish Association for Composite Materials, Czech Society for New Materials and Technologies, Danish Metallurgical Society, European Composites Industry Association

U.S.A: The Materials Information Society, American Physical Society, Magnetic Materials Producers Association, Materials Research Society, The Minerals, Metals & Materials Society, American Chemical Society

Asia-Pacific: International Association of Advanced Materials, Chinese Society for Composite Materials, Materials Research Society of Singapore, The Association of East Asian Research Universities, Australian Composite Structures Society, Japan Society for Composite Materials, Chinese Society for Metals.

Track 2: Advanced Nano Materials

Nanomaterial or nanostructured materials are characterised into nanocomposite, nanofoam, nanoporous material and nanocrystalline materials depending on the phases of matter. The inorganic nanomaterials such as nanowires, nanorods, quantum dots are used in optoelectronics because of their optical and electrical properties that depend on their size and shape. These nanomaterials are potentially used in organic materials based optoelectronic devices which find its application in Organic solar cells, OLEDs etc. The functioning of these devices is ruled by photo induced processes such as electron transfer and energy transfer. Hence it is necessary to have enhanced understanding of photoinduced processes in organic/inorganic nanomaterial composite for their application in optoelectronic devices. Nanoparticles is also been used as chemical catalyst which are very good adsorbents. Nanofabrication is a significant subfield of nanotechnology associated with energy. The method of producing and designing devices at nanoscale is called as Nanofabrication. The nanofabricated devices help in capturing, storing and transfer of energy in a better way to meet the existing energy technologies, thus utilized in the development of consumer products. The benefits include increased heating and lightning efficiency, improved electrical storage capacity and reduction in pollution which enables the capital investment in the nanotechnology research.

Advanced Nanomaterials Societies and Associations

Europe: European Nanoscience and Nanotechnology Association, Nanotechnology Industries Association, Russian Society of Scanning Probe Microscopy and Nanotechnology

USA: American Nano Society, International Association of Nanotechnology, Nanotechnology and Nanoscience Student Association (NANSA), American Bar Association Section Nanotechnology Project, American Chemical Society, Microscopy society of America

Asia: Asian Nanoscience and Nanotechnology Association, International association of Nanotechnology, Chinese Society of Nanotechnology , Korean Society of Nanotechnology, Japanese Society of Nanotechnology

Track 3: Hydrogen Energy and Fuel Cell technology

Hydrogen which is simple, abundant, zero-emission fuel in the earth is used as an energy carrier for broad range of application. Under normal temperature and pressure hydrogen is colorless, nontoxic, non-metallic and combustible gas and could be used as a substitute to fossil and liquid fuels. Hydrogen energy have been potentially used in cars, houses, mobile power, to launch satellite vehicles, industries, in telecom tower for power back up, to produce electricity, internal combustion engines and many more applications. Hydrogen is produced from numerous resources such as natural gas, coal (carbon sequestration), nuclear energy, and biomass, solar, hydro-electric power and geothermal by varied processes. Hydrogen originates from several organic compounds, particularly hydrocarbons which are used to make other fuel such as natural gas, gasoline, methanol and propane. Hydrogen is being separated from hydrocarbons by the process of reforming, electrolysis.Water splitting, one of the electrochemical processes is the more significant research area. Pure form of hydrogen has its capability to operate fuel cell in zero- emission electric vehicles. The future of hydrogen is to join electricity as a significant energy carrier and can be transported to necessary location.

Hydrogen Energy Societies and Associations

Europe: Spanish Hydrogen Association, French Hydrogen Association, The German Hydrogen and Fuel Cell Association, North Atlantic Hydrogen Association, Italian Hydrogen and Fuel Cell Association, Dutch Hydrogen Association, Norwegian Hydrogen Association, Spanish Hydrogen Association - Hydrogen and Fuel Cells Technologies, Swiss Hydrogen Association, UK Hydrogen and Fuel Cells Association.

USA: Fuel Cell and Hydrogen Energy Association (FCHEA), International association of Hydrogen Energy, National Hydrogen Association, Australian Association for Hydrogen Energy, Canadian Hydrogen and Fuel Cell Association

Asia: Hydrogen Association of India, Hydrogen Energy Systems Society of Japan, The Korean Hydrogen and New Energy Society, Indian Association for Hydrogen Energy and Advanced Materials

Track 4: Solar Energy Materials

The emerging potential power generation since last decade is solar technology. The propagation of research on materials science and technology associated to photothermal, photoelectrochemical, photovoltaic, solar energy conversion is projected to be by Solar Energy Materials and Solar cells. Solar absorber devices, radiative cooling system, heat storage materials are some of the photothermal devices. Photochemical and photoelectrochemical devices include photocatalysis, photoelectrodes, solar desalination system, photoconversion and their applications. Light trapping, solar concentrators, imaging and non-imaging optical collectors, texturing are the optical properties of materials

Solar Energy Materials Societies and Associations

Europe: International Solar Energy Society, Czechoslovak Solar Energy Society (CSSE), ISES Austria, Danish Solar Energy Society (DKSES), Solar Energy Society of Ireland, Norwegian Solar Energy Society, Asociación Espanola de Energia Solar (AEDES).

USA: American Solar Energy Society, Solar Energy Industries Association, American Solar Energy Society, American Council for an Energy-Efficient Economy (ACEEE), Association of Professional Energy Managers (APEM), EnergyTrust of Oregon, Solar Energy Society of Canada INc. (SESCI)

Asia: Solar Energy Society of India, Chinese Solar Energy Society (CSES), Asociación Costarricense de Energia Solar, Egyptian Solar Energy Society (ESES), Japansese Solar Energy Society, Korean Solar Energy Society (KSES)

Track 5: Polymer Energy Materials

Polymeric materials are vital for the future electronic devices and flexible electronic applications. The research based on the electronic, structural and chemical properties of polymeric materials are widely used in the applications of microelectronics and low cost solar materials. Their applications include lithium-ion polymer battery (LiPo), electro active polymers, polymeric surface, Crystallization of polymers, cationic & plasma polymerization, polymer brush etc... In recent times, self-healing materials industrialized for energy harvesting and storage are all polymerâ€based materials. Those self-healing Energy Harvesting Devices include nanogenerators, Photovoltaics, solar cells, supercapacitors and lithium batteries. Recently lightweight composite material is discovered for energy storage in flexible electronics, electric vehicles and aerospace applications

Polymer Energy Materials Societies and Associations

Europe: The Polymer Society UK, Telford Polymer Association, European Polymer Dispersion and Latex Association, Polish Chemical Society, British Plastic Association, Association of Plastics Manufacturers in Europe, European Council for Plasticisers & Intermediates.

USA: American Chemical Society (Division of Polymer Chemistry), American Physical Society, American Chemical Society Division of Polymeric Materials, American Plastics Council, Brazilian Polymer Association, Plastic Industry Association USA, Society of Plastics Engineers, Society of the Plastics Industry.

Asia: Asian Polymer Association, Society for Polymer Science, Polymer Society of Thailand, Federation of Polymer Societies, Polymer society of Japan.

Track 6: Crystalline Porous Materials

Crystalline porous materials is the trending research area in the field of proton conducting materials that includes Coordination polymers (CPs), polyoxometalates (POMs), covalent organic frameworks (COFs) and metal–organic frameworks (MOFs). Among those are two major evolving and developing families of crystalline porous materials, Covalent-organic frameworks (COFs) and Metal–organic frameworks (MOFs). These materials are categorized by their extreme porosity, wonderful structural density and flexible functional tenability at molecular level which find its application in batteries, supercapacitors and electrochemical energy storage devices. The crystalinity of materials offers stability for the electrochemical treatment and porosity (high surface area) helps in diffusion of electrolytes and mobility of ions.

Crystalline Porous Materials Societies and Associations

Europe: European Materials Research Society, Austrian Society for Metallurgy and Materials, Federation of European Materials Societies, The European Semiconductor Industry Association (ESIA), Czech Society for New Materials and Technologies

U.S.A: American Physical Society, Magnetic Materials Producers Association, Materials Research Society, The Materials Information Society, The Minerals, Metals & Materials Society, American Chemical Society.

Asia-Pacific: Materials Research Society of Singapore, International Association of Advanced Materials, The Association of East Asian Research Universities, Chinese Society for Metals.

Track 7: Catalysis and Energy Materials

The materials for catalysis and energy with electrochemical properties are appropriately used in energy storage applications such as batteries and electro catalysts. Metal nanoparticles are also widely explored heterogeneous catalysis. The size of these metal nanostructures manipulates the activity of catalysis. The novel energy research approaches to overcome the usage of fossil fuels is to develop chemical energy storage of renewable energy. Materials with emerging energy technologies such as super capacitors, renewable energy sources, thermoelectric devices, photovoltaic cells, piezoelectric, ferroelectric materials will be sustainable to withstand the global energy demand. The Single- atom catalyst (SACs) which has single metal atom attached on support has low particle size with increased free energy. The suitable interaction with other isolated atoms creates stable active sites with high selectivity.

Catalysis and Energy Materials Societies and Associations

Europe: European Federation of Catalysis Societies, Netherlands Institute for Catalysis Research, Finnish Catalysis Society, European Materials Research Society, Federation of European Materials Societies.

U.S.A: The International Association of Catalysis Societies, North American Catalysis Society, American Physical Society, The Minerals, Metals & Materials Society, American Chemical Society

Asia-Pacific: The catalysis society of India, Asia-Pacific Association of Catalysis Societies, Catalysis Society of Australia, The Catalysis Society of China, High Energy Materials Society of India, International Association of Advanced Materials, Materials Research Society of Singapore

Track 8: Biomaterials for Energy production

With increasing energy demand, world’s energy supply is likely to drop in the near future due to the declining fossil fuel feed stocks hence science and technology have to find alternative resources for the production of fuels. Currently, biomass and food waste is considered as the renewable feedstock for the production of chemicals and fuels in Europe. These renewable materials are utilized for the production of biopolymers, bioplastics and bioethanol. Biomolecules such as peptides and proteins are under research to create new nanomaterials to enhance the efficiency of photovoltaic such as solar cells and other electronic devices. Bioproteins power can also be harnessed for non-biological materials applications. Biomaterials have also been used as electrode materials in rechargeable lithium batteries. The nanostructure of these materials improves their electrochemical activity, thus enhance the battery performance.

Biomaterials for Energy Production Societies and Associations

Europe: European Society for Biomaterials, UK Society for Biomaterials, Romanian Society For Biomaterials, The Hellenic Society for Biomaterials, Scandinavian Society for Biomaterials, Italian Society for Biomaterials.

USA: Society for Biomaterials, Canadian Biomaterials Society, The International Society of Biomedical Polymers and Polymeric Biomaterials (ISBPPB), World Biomaterials Congress.

Asia: The Korean Society for Biomaterials, Japanese Society for Biomaterials, Chinese Society for Biomaterials, Society for Biomaterials and Artificial Organs.

Track 9: Advanced Graphene & 2D Materials

2D materials (2D allotropes of several elements or compounds) also mentioned as single layer materials are crystalline in nature containing single layer of atoms. These materials find its application in semiconductors, electrodes, water purification and photovoltaic. Graphene, the global first 2-D carbon material also called as “wonder material” is a transparent material with one atom thick sheet. Graphene shows unique properties such as high efficient electrical conductivity, thermal conductivity, and current density are hundred times stronger than steel. It is the most ideal material for applications such as extremely strong composite materials, flexible displays and nano-transistors. The worldwide graphene market is predictable to range USD 278.47 Million by 2020, with a development of 42.8% from 2015 to 2020 in electronic devices, composite materials, semiconductor materials and battery technologies. Graphene based composite materials are available for commercial purpose in tennis rackets, bikes and skis. The projecting energy associated areas where graphene will have an effect is sun powered solar cells, supercapacitors, catalysis and lithium-particle batteries.

Advanced Graphene and 2D Materials Societies and Associations

Europe: Federation of European Materials Societies, Austrian Society for Metallurgy and Materials, The European Semiconductor Industry Association (ESIA), European Materials Research Society

U.S.A: Graphene Stakeholders Association (GSA), Semiconductor Research Corporation, National Graphene Association, The Graphene Council, American Chemical Society - Nanotechnology Safety Resources, International Association of Nanotechnology, ASME Nanotechnology Institute

Asia-Pacific: Semiconductors Society of India, Materials Research Society of Singapore, Russian Nanotechnology Corporation, Asian Nanoscience and Nanotechnology Association, International association of Nanotechnology.

Track 10: Batteries and Solid Electrolyte Materials

Battery is an electric device comprises of one or more electrochemical cells uses external electric connections to power the electrical devices such as smartphones, flashlights and electric cars. There are two types of batteries, primary and secondary. The former type of batteries are used once and discarded, while the later type can be discharged and recharged several times. Batteries convert chemical energy directly to electrical energy that consists of some number of voltaic cells. The voltage established across a cell's terminals is subject to the energy release of the chemical reactions of its electrodes and electrolyte. Solid-state battery was invented in 2017 by John Goodenough where both the electrodes and electrolyte will be in solid state.Solid electrolytes also termed as superionics are materials that reveals high values of ionic conductivity and is widely studied materials for solid state batteries, gas sensors, fuel cells, batteries and electrochromic devices. Solid electrolytes are the potential materials to replace organic electrolytes that are flammable and toxic. This new type of battery is “three times energy denser”, safer, faster charging and used for longer lasting rechargeable batteries such as mobile devices, stationary energy storage and electric vehicles. Photovoltaic (PV) cells are devices that engross light and convert directly into electricity (e.g., solar cell). PV cell is categorized into three main types inorganic, organic and photoelectrochemical. Inorganic PV cells are commercially available as mono-crystalline, multi-crystaline and amorphous. The Industrial batteries market for end-user industry is expected to reach USD 10.84 Billion by 2021, at a CAGR of 6.5% between 2016 and 2021. The advancement in the market can be primarily due to the increasing demand from the locomotive sector, development in renewable energy sector, enlarged recycling efficiency of lead-acid and lithium-based industrial batteries, and greater performance of industrial batteries in terms of energy density.

Batteries and Energy Devices Societies and Associations

Europe: Danish Battery Society, The Rechargeable Battery association, Battery Vehicle Society (BVS) , European Portable Battery Association, Argentinean Battery Association, British Battery Industry Federation

U.S.A: Canadian Battery Association, Energy Storage Association, Battery Council International (BCI), Fuel Cell and Hydrogen Energy Association

Asia-Pacific: Australian Battery Industry Association, Japan Battery Association, Taiwan Fuel Cell Partnership (TFCP), Electric Vehicle Association of Asia Pacific (EVAAP), Korea Battery Industry Association

Track 11: Optical, Electrical and Magnetic Materials

Optical materials and coatings play a significant role in defining the effectiveness of solar conversion processes. The coating materials for optical devices are under research development. Few of the coating materials currently in use are heat mirrors, reflector materials, selective absorbers, fluorescent concentrator materials, cold mirrors, holographic films, optical switching films, radiative cooling surfaces and transparent insulation materials. These materials help in improving the novelty of solar energy conversion, energy-efficient windows, photovoltaic, and other hybrid designs. The functioning of electronic devices is efficiently controlled by switching devices. The innovation in electronic and photonic nanomaterials will results in the advancement of computing devices and solid-state lightning. Existing research comprises of organic semiconductors, thin films, nanostructures and bulk crystal growth. The silicon carbide semiconductor market is projected to raise $3182.89 Million by 2020, at an estimated CAGR of 42.03%. Magnetized materials are termed as ferromagnetic materials that comprises of cobalt, iron, nickel, alloys and rare earth elements. These ferromagnetic materials find its application in medicine as contrasting agent for MRI scans.

Optical, Electrical and Magnetic Materials Societies and Associations

Europe: European Optical Society, United Physical Society of Russian Federation, Danish Optical Society, Italian Optical Society, Austrian Physical Society, Finnish Optical Society, French Physical Society.

U.S.A: Optical Society of America (OSA), American Physical Society, IEEE Photonics Society, IEEE Lasers and Electro-Optics Society, International Society of Optical Engineering

Asia-Pacific: Optical Society of Japan, Optical Society of Hong-Kong, Optical Society of Korea, Optical Society of China

Track 12: Energy Harvesting Materials

Energy harvesting or scavenging is the process of capturing small amounts of energy which would be lost in the form of heat, light, sound, vibration and the stored energy is used to improve the efficiency for wireless sensor network, wearable electronics and automotive devices. These materials are capable of replacing batteries for small, low power electronic devices and are environmentally friendly. The waste energy can be harvested by different materials. Thermoelectric and pyroelectric materials help in capturing heat and are transformed into electric power. The vibration, movement and sound are captured by piezoelectric materials that are transformed into electric power. Initially, thermoelectric materials are limited due to small conversion efficiency, but the occurrence of nanostructured thermoelectric materials led to significant development in enhancing thermoelectric properties. The pyroelectric effect is being used in sensors.

Energy Harvesting Materials Societies and Associations

Europe: European Materials Research Society, Spanish Association for Composite Materials, Czech Society for New Materials and Technologies, Danish Metallurgical Society, European Composites Industry Association, Federation of European Materials Societies

U.S.A: The Materials Information Society, American Physical Society, Magnetic Materials Producers Association, Materials Research Society, American Chemical Society

Track 13: Emerging Technologies for Energy Applications

The increasing power consumption in developing regions enhances the power infrastructure and concern regarding the use of renewable power supplies. The governments worldwide are increasingly investing in renewable energy sources such as solar and wind. As per the global forecast to 2023, the power electronics market by materials, device type and application is predictable to increase from USD 39.03 Billion in 2018 to USD 51.01 Billion by 2023, increasing at a CAGR of 5.5% between 2018 and 2023. The growth of this market is endorsed to the advancement of power electronics and developing demand for energy-efficient battery-power portable devices. The major players in the power electronics market are Texas Instruments in US, On Semiconductor in US, Infineon Technologies in Germany, STMicroelectronics in Switzerland, NXP Semiconductors in Netherland, Vishay Intertechnology in US, Maxim Integrated Products in US etc., The major areas for emerging technologies are Storage, Smart grid and Electricity generation. Emerging Energy storage encompasses novel, economical ways of storing energy in the form of improved batteries, fuel cells, hydrogen energy storage and transport. Smart grid technologies enable efficient generation and use of energy. Emerging Electricity generation is characterized by the technology to generate power from unused resources.

Emerging Technologies for Energy Applications Societies & Associations

Europe: The European Semiconductor Industry Association (ESIA), Federation of European Materials Societies, Spanish Association for Composite Materials, Austrian Society for Metallurgy and Materials, Czech Society for New Materials and Technologies, European Materials Research Society, Danish Metallurgical Society, European Composites Industry Association

U.S.A: American Physical Society, Magnetic Materials Producers Association, Materials Research Society, Society for Biomaterials, The Minerals, Metals & Materials Society, The Materials Information Society, American Chemical Society

Asia-Pacific: International Association of Advanced Materials, Materials Research Society of Singapore, The Association of East Asian Research Universities, Australian Composite Structures Society, Chinese Society for Composite Materials, Japan Society for Composite Materials, Chinese Society for Metals

Market Analysis

Summary:

Advanced Energy Materials Conference provides wide range of sessions that discourse the current innovations and novel approaches for the expansion of energy materials to meet the global desires. Advanced Energy Materials 2022 covers major subjects such as fuel cells, organic and inorganic photovoltaic, batteries and super capacitors, Piezoelectronics, hydrogen generation and storage, thermoelectric, photo catalysis, solar fuels and thermosolor power.

The organizing committee of Advanced Energy Materials 202 2 is arranging for an exciting and enlightening conference program this year also that embraces plenary talks, keynote lectures, oral presentations, symposia, workshops on diverse topics, poster presentations and exhibitions for participants from all over the sphere. We are pleased to invite you for this conference on Advanced Energy Materials and Research where you will be sure of having prominent experience from worldwide scholars.

For more details please visit: Energy Materials Conferences

Important and Scope

Energy is a part of Science in which materials technology plays an important role as Advanced Energy Materials to meet the needs of future environment. The increasing ecological problems such as energy storage, generation and conservation are the major drivers of Energy Materials technology. There is a need of developing sustainable energy production and consumption to achieve the socio economic and environmental targets.

As per the global forecast to 2023, the power electronics market by materials, device type and application is predictable to increase from USD 39.03 Billion in 2018 to USD 51.01 Billion by 2023, increasing at a CAGR of 5.5% between 2018 and 2023. The growth of this market is endorsed to the advancement of power electronics and developing demand for energy-efficient battery-power portable devices.

Major Energy Materials Societies and Association around the globe

The European Semiconductor Industry Association (ESIA)
Federation of European Materials Societies
Spanish Association for Composite Materials
European Materials Research Society
European Composites Industry Association
American Physical Society
Materials Research Society
American Chemical Society
International Association of Advanced Materials
Materials Research Society of Singapore
Australian Composite Structures Society
Chinese Society for Composite Materials
Japan Society for Composite Materials
European Optical Society
United Physical Society of Russian Federation
Optical Society of America (OSA)
IEEE Photonics Society
IEEE Lasers and Electro-Optics Society
International Society of Optical Engineering

To Collaborate Scientific Professionals around the World

Conference Date May 24-25, 2023

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Speaker Opportunity

Poster Opportunity E-Poster Opportunity

Useful Links

Past Conference Report

Advanced Energy Materials 2022 Conference

Supported By

Innovative Energy & Research Journal of Fundamentals of Renewable Energy and Applications Journal of Material Sciences & Engineering

All accepted abstracts will be published in respective Conference Series International Journals.

Abstracts will be provided with Digital Object Identifier by

Advanced Energy Materials and Research

May 24-25, 2023 Berlin, Germany

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