Energy storage materials

Gum Arabica is a natural plant gum that exudates a carbohydrate type and is an electroactive biopolymer. Gum Arabica and its complexes have potential applications in developing ionic devices such as batteries, sensors, bio-sensors, and other electronic applications, in addition to solar material, energy storage material and nanoscience. Biopolymers obtained from bacteria are rapidly emerging because they are biodegradable and available in abundance. Simple methods are being developed to grow and harvest the polymers to exploit them for numerous industrial and biomedical applications. Electronic structures and conduction properties of biopolymers are also discussed in Part III. 

Ma C, Lyu Y, Li H (2014) Fundamental scientific aspects of lithium batteries (Vll)—positive electrode materials. Energy Storage Sci Tech 3 53-65... 

Titanium alloyed with kon is a candidate for soHd-hydride energy storage material for automotive fuel. The hydride, FeTiH2, absorbs and releases hydrogen at low temperatures. This hydride stores 0.9 kWh /kg. To provide the energy equivalent to a tank of gasoline would thus requke about 800-kg... 

It has been estimated that >90% of the carbohydrate mass in nature is in the form of polysaccharides. In living organisms, carbohydrates play important roles. In terms of mass, the greatest amounts by far are stmctural components and food reserve materials, in that order and both in plants. However, carbohydrate molecules also serve as stmctural and energy storage substances in animals and serve a variety of other essential roles in both plants and animals. 

The facile, photoinduced valence isomerization of ethyl 1//-azepine-l-carboxylate to ethyl 2-azabicyclo[3.2.0]hepta-3,6-diene-2-carboxylatehas been studied as a potential solar energy storage system.101102 Unfortunately, the system proved to be inefficient due to build up of polymeric material during the thermally induced, exothermic retro-reaction. 

Thin-film solid electrolytes in the range of lpm have the advantage that the material which is inactive for energy storage is minimized and the resistance of the solid electrolyte film is drastically decreased for geometrical reasons. This allows the application of a large variety of solid electrolytes which exhibit quite poor ionic conductivity but high thermodynamic stability. The most important thin-film preparation methods for solid electrolytes are briefly summarized below. 

At present batteries worth more than 30 billion USD are produced every year and the demand is still increasing rapidly as more and more mobile electronic end electric devices ranging from mobile phones to electric vehicles are entering into our life. The various materials required to manufacture these batteries are mostly supplied by the chemical industry. Ten thousands of chemists, physicists and material scientists are focusing on the development of new materials for energy storage and conversion. As the performance of the battery system is in many cases a key issue deciding the market success of a cordless product there is in fact a kind of worldwide race for advanced batteries. 

---