March 22, 2021    London, UK

Advance Energy Materials Research

Webinar on Advanced Energy Materials and Research

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March 22, 2021

Advance Energy Materials Research

Webinar on Advanced Energy Materials and Research

Novel Innovations in Energy Materials to encounter Global Challenges during the COVID-19

Briefly Know About This Event

Longdom extends our immense pleasure and honour to invite you to attend Webinar on Advanced Energy Materials scheduled on March 22, 2021. It is focusing on the theme “Novel Innovations in Energy Materials to encounter Global Challenges during the COVID-19” to enhance and explore knowledge among academics and industry personnel dealing with Advance Energy materials, Nano Materials, soalr energy materials, Polymer Enegy materials, etc., and its related subjects. Our webinar agenda is to establish corporations and exchanging ideas and it aims to provide the right stage to present stimulating Keynote talks, plenary sessions, and panel discussion.

Sessions

The expanding energy interest because of developing worldwide popular and the basic connection between Energy, climate and manageability lead to novel disclosures and headway in the field of Energy Materials looking for elective assets. The great prerequisite to change feedstock into reasonable fuel sources is the impetus for better sun based cells and energy stockpiling materials.

Nanomaterial’s are composed of structures at the Nano scale, usually achieved via specifically designed self-assembly processes. They acquire unique electronic, optical, mechanical, magnetic, catalytic properties, which cannot be achieved without their Nano-architecture. Such advanced nanomaterial’s provide unprecedented opportunities for tuning their properties in a very broad range. 

Hydrogen is also found in many organic compounds, notably the hydrocarbons that make up many of our fuels, such as gasoline, natural gas, methanol, and propane. Hydrogen can be separated from  hydrocarbons through the application of heat – a process known as reforming. Currently, most hydrogen is made this way from natural gas. An electrical current can also be used to separate water into its components of oxygen and hydrogen.

Solar Energy Materials & Solar Cells is intended as a vehicle for the dissemination of research results on materials science and technology related to photovoltaic, photo thermal and photo electrochemical solar energy conversion. Materials science is taken in the broadest possible sense and encompasses physics, chemistry, optics, materials fabrication and analysis for all types of materials

Polymer Materials for Energy and Electronic Applications is among the first books to systematically describe the recent developments in polymer materials and their electronic applications. It covers the synthesis, structures, and properties of polymers, along with their composites. In addition, the book introduces, and describes, four main kinds of electronic devices based on polymers, including energy harvesting devices, energy storage devices, light-emitting devices, and electrically driving sensors.

Each atom in a graphene sheet is connected to its three nearest neighbors by a σ-bond, and contributes one electron to a conduction band that extends over the whole sheet. This is the same type bonding seen in carbon nanotubes and polycyclic aromatic hydrocarbons, and (partially) in fullerenes and glassy carbon. These conduction bands make grapheme a semimetal with unusual electronic properties that are best described by theories for massless relativistic particles.

A solid-state battery is a battery technology that uses solid electrodes and a solid electrolyte, instead of the liquid or polymer gel electrolytes found in lithium-ion or lithium polymer batteries. Materials proposed for use as solid electrolytes in solid-state batteries include ceramics (e.g. oxides, sulfides, phosphates), and solid polymers. Solid-state batteries have found use in pacemakers, RFID and wearable devices. They are potentially safer, with higher energy densities, but at a much higher cost. Challenges to widespread adoption include energy and power density, durability, material costs, sensitivity and stability.

Electro-optics is a branch of electrical engineering, electronic engineering, materials science, and material physics involving components, devices (e.g. Lasers, LEDs, waveguides etc.) and systems which operate by the propagation and interaction of light with various tailored materials. It is essentially the same as what is popularly described today as photonics. It is not only concerned with the "Electro-Optic effect". Thus it concerns the interaction between the electromagnetic (optical) and the electrical (electronic) states of materials.

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