Kiel University and equipment manufacturers RENA Technologies present new approach at the Hannover Messe. Longer life times, larger ranges and faster recharging - developments such as electric mobility or the miniaturisation of electronics require new storage materials for batteries. With its enormous storage capacity, silicon would potentially have decisive advantages over the materials used in commercial available lithium-ion batteries. But due to its mechanical instability, it has so far been almost impossible to use silicon for storage technology.
A research team from the Institute for Materials Science at Kiel University, in cooperation with the company RENA Technologies GmbH, is developing anodes made of 100% silicon, as well as a concept for their industrial production. Through targeted structuring of its surface at the micrometer level, the team can fully exploit the storage potential of silicon. This opens up a completely new approach to rechargeable batteries, as well as the energy storage of tomorrow. This week, the partners are presenting the production and potential use of silicon anodes at the Hannover Messe (23 – 27 April), at the CAU booth (Hall 2, C07).
Silicon has long been a potential candidate for the e-lectric mobility, according to materials scientist Dr Sandra Hansen. "Theoretically, silicon is the best material for anodes in batteries. It can store up to 10 times more energy than graphite anodes in conventional lithium-ion batteries." Electric cars could drive further, smartphone batteries could last longer, and recharging would be significantly faster. An additional advantage of the semiconductor material is its unlimited availability - after all, sand consists largely of silicon dioxide. "Silicon is the second most abundant element on earth after oxygen, and thus an almost unlimited cost-effective resource," said Hansen.
However, so far the life time of silicon anodes was far too short to really use them in chargeable and rechargeable batteries. The reason for this is the high sensitivity of the material. During charging, lithium ions move back and forth between the anode and cathode. Silicon, as the material with the highest energy density, can take up a remarkable number of lithium ions. While doing so, it expands by 400 percent, and would break in the long run.
At the Institute for Materials Science in Kiel, silicon has been researched for almost 30 years. The findings to date, combined with the silicon experience of RENA Technologies GmbH gained from solar technology, should contribute to producing battery anodes made from 100% silicon. This would enable maximum use of their storage potential - anodes in conventional rechargeable batteries contain only approximately 10-15 percent silicon. To pursue this goal, the joint research project "Development and characterisation of large, porous Si film anodes for lithium-sulphur-silicon energy storage" (PorSSi) kicked off last year, which has gained a total of one million Euros in funding from the Federal Ministry of Education and Research (BMBF, more details see below). The result at the end should be a high-performance silicon battery, along with a concept for its cost-effective industrial production.
"The cooperation between Kiel University and RENA is a highly-efficient combination of decades of experience in fundamental research with industrial process and equipment development expertise," emphasised Dr Holger H. Kühnlein, Senior Vice President of Technology at RENA Technologies GmbH. "In this way, we can transfer the results from university research into industrial applications as soon as possible," added Professor Rainer Adelung, head of the Functional Nanomaterials working group at Kiel University, where many of the discoveries to date about silicon were made. Adelung: "This is real innovation transfer."
Dr. Sandra Hansen
Head of the PorSSi project at Kiel University
More information on the project:
"In order to increase the cycling stability of silicon anodes in batteries, we need to understand exactly what happens when they expand while charging," said Hansen. During her PhD thesis, she discovered that silicon behaves much more flexible when it is produced in the form of a thin wire. These findings are now transferred to porous silicon - its free volume leaves more space for expansion. To prevent the contacts with the electrode from breaking, Hansen has co-developed and patented a method for a stable connection between the two. The team wants to manufacture the counterpart to the anode - the cathode - from sulphur. "A sulphur cathode provides the maximum possible storage capacity. So in this project, we combine two materials that promise really high performance from the battery," said Hansen.
Hansen wants to improve the life time of silicon anodes even further, through special quality control during manufacturing: they are produced from a so-called wafer. Using a lithographic etching process, the surface of this flat disc is structured on a nano scale, to give it specific properties. With an enhanced method from the field of solar technology, Hansen then carries out a visual inspection of the surface over a period of time. In this way, it can be determined at which point in the manufacturing process uneven areas have developed on the surface, which reduce the performance of the anode.
"At the moment, this process still takes a long time and is very expensive. If we can manage to transfer it from a silicon wafer to a porous film, we could etch them in just a few minutes," said Hansen. Through the cooperation with RENA, the research findings flow directly into the development of new etching systems. A prototype will be produced in the course of the three-year project period, and installed at the Faculty of Engineering in Kiel.
Project title: Development and characterisation of large, porous Si film anodes for lithium-sulphur-silicon energy storage (PorSSi)
Duration of funding: 01.09.2017 - 31.08.2020
Funding amount: One million Euros (500,000 Euros in Kiel)
Project partner: RENA Technologies GmbH
Coordination: Benedict Straub, RENA Technologies GmbH
Project manager: Sandra Hansen, Kiel University
BMBF funding line: "Battery materials for future electric mobile and stationary applications (Batteries 2020)"
Title: Method for producing surface discharge electrodes and semifinished product for carrying out the method
No. WO 2016/037610A1
Inventor: Sandra Hansen (nee Nöhren), Jörg Bahr and Jürgen Carstensen
Previous publications on the project topic:
Hansen et al., J. Power Sources 2018, 381, 8-17, https://doi.org/10.1016/j.jpowsour.2018.01.085
Hansen et al., J. Power Source, 2017, https://doi.org/10.1016/j.jpowsour.2017.03.025
Hansen et al., J. Electrochem. Soc. 2016, https://doi: 10.1149/2.0811614jes
Photos are available to download:
The Kiel research team manufactures anodes for their innovative silicon batteries from silicon wafers like this one. An etching process gives the originally blank discs a porous surface - and a colourful sheen. The porous silicon layer can be bonded particularly well with a copper electrode. The resulting extremely thin anode can be peeled off like a film.
Photo/Copyright: Siekmann, Kiel University
In the laboratory at the Faculty of Engineering, Hansen is constructing the first prototypes of silicon batteries, to test how many charge cycles they can last. There is no oxygen in this so-called "glove box", otherwise the lithium in the battery would oxidise.
Photo/Copyright: Julia Siekmann, Kiel University
When charging the battery, silicon expands by 400 percent, and the delicate material could break. It is much more flexible in the form of such micro-wires, as Hansen was able to prove in her doctoral thesis. But this kind of manufacturing is still too expensive for industrial production.
Photo/Copyright: Sandra Hansen
During the whole week Dr. Sandra Hansen presents their new approach how to fabricate silicon anodes at the Hannover Messe.
Foto/Copyright: Claudia Eulitz, Kiel University
In 2018, Kiel University (CAU) will once again present its excellent research at the Hannover Messe. Under the motto "Ways to Solutions" the state university demonstrates: science affects society in many different ways. It contributes to exchanges, solves tricky problems and creates new scenarios. All this awaits guests in Hall 2 (Research & Technology). This time, together with our partners: State of Schleswig-Holstein, the City of Kiel and the European XFEL. Participation at the trade show will focus on presentations and exhibits associated with cutting-edge research, the transfer of knowledge, patents and initiatives to establish companies. Presentations and panel discussions will round off the varied programme during the week. All details can be found at http://www.uni-kiel.de/hannovermesse/en.
Christian-Albrechts-Universität zu Kiel
Press, Communication and Marketing, Dr Boris Pawlowski, Text/editing: Julia Siekmann
Postal address: D-24098 Kiel, Germany,
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