#Glass for battery electrodes In this regard researchers are diligently looking for new materials that exhibit a greater energy density and charging capacity but which are no heavier or larger than those used in today's lithium-ion batteries. Today's batteries provide a reliable power supply for our smartphones electric cars and laptops but are unable to keep up with the growing demands placed on them. Dr Semih Afyon a scientist at the Electrochemical Materials Institute sums up the fundamental idea that is driving battery research: What we need is new chemistry and novel compounds to obtain safe better and longer-lasting batteries. ETH researchers led by Afyon and Reinhard Nesper professor emeritus of chemistry have made now a discovery. Over the course of their several years of research they discovered a material that may have the potential to double battery capacity: vanadate-borate glass. Researchers are using the glass as a cathode material as recently reported in Scientific Reports a journal from the publishers of Nature. The material is made of vanadium oxide (V2o5) and lithium-borate (Libo2) precursors and was coated with reduced graphite oxide (RGO) to enhance the electrode properties of the material. The researchers used a vanadium-based compound because vanadium is a transition metal with various oxidation states which can be exploited to reach higher capacities. In crystalline form vanadium pentoxide can take three positively charged lithium ions--three times more than materials presently used in cathodes such as lithium iron phosphate. However crystalline vanadium pentoxide cannot release all of the inserted Li-ions and only allows a few stable charge/discharge cycles. This is because once the lithium ions penetrate the crystalline lattice during the loading process the lattice expands. As a result an electrode particle swells as a whole i e. it increases in volume only to shrink again once the charges leave the particle. This process may lead to instabilities in the electrode material in terms of structural changes and contact losses. Researchers therefore had to find a way to retain the structure of the initial material while maximizing the capacity and also maintaining its ability to take the charges which is devised how they the idea of using vanadium as a glass rather than in its crystalline form. In glass a so-called amorphous material atoms do not arrange themselves in a regular lattice as they do when they are in a crystalline state. Instead the atoms exist in a state of wild disarray. To produce the cathode material Afyon and his colleagues blended powdered vanadium pentoxide with borate compounds. Borate is a glass former; that's why the borate compounds were used and the resulting glass compound is a new kind of material neither V2o5 nor Libo2 at the end the researcher says. The materials scientists melted the powder at 900#C and cooled the melt as quickly as possible to form glass. The resulting paper-thin sheets were crushed then into a powder before use as this increases their surface area and creates pore space. One major advantage of vanadate-borate glass is that it is simple and inexpensive to manufacture states Afyon. This is expected to increase the chance of finding an industrial application. To produce an efficient electrode the researcher coated the vanadate-borate powder with reduced graphite oxide (RGO. This increases conductivity while at the same time protecting the electrode particles. However it does not impede electrons and lithium ions as they are transported through the electrodes. Afyon used this vanadate-borate glass powder for the battery cathodes which he then placed in prototypes for coin cell batteries to undergo numerous charge/discharge cycles. During initial trials with vanadate-borate electrodes which were made not with material coated in RGO the discharge capacity dropped drastically after 30 charge/discharge cycles when the current rate was increased to 400 milliamp per gram. In contrast when the RGO coating was used the capacity was quite stable at high rates and it remained at a consistently high level after more than 100 charge/discharge cycles. One battery with an RGO-coated vanadate-borate glass electrode exhibited an energy density of around 1000 watt-hours per kilogram. It achieved a discharge capacity that far exceeded 300 mah/g. Initially this figure even reached 400 mah/g but dropped over the course of the charge/discharge cycles. This would be enough energy to power a mobile phone between 1. 5 and two times longer than today's lithium-ion batteries Afyon estimates. This may also increase the range of electric cars by one and a half times the standard amount. These figures are still theoretical. The researchers have applied already for a patent for their new material. They also worked with industry partners on the development. Our focus was on practical applications as well as on fundamental research says the researcher. A new concept usually takes around 10 to 20 years to gain a foothold in the market. The researcher's positive results with the vanadate-borate glass have encouraged them to continue their research in this area. Afyon currently works as a project leader in a research consortium led by Jennifer Rupp professor of electrochemical materials focused on developing an innovative solid-state battery. They are already using and testing the vanadate-borate electrode in this system and their next step is to optimise the system. In particular they have to increase the number of charge/discharge cycles significantly which could be achieved by improving battery and electrode designs as well as by using coatings other than reduced graphite oxide i

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