| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Hollenkamp, Anthony
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (20/20 displayed)
- 2022Sustainable cyanide-C60 fullerene cathode to suppress the lithium polysulfides in a lithium-sulfur batterycitations
- 2022Coating Methods
- 2021Long-Life Power Optimised Lithium-ion Energy Storage Device
- 2021Comparing Physico-, Electrochemical and Structural Properties of Boronium vs Pyrrolidinium Cation Based Ionic Liquids and Their Performance as Li-ion Battery Electrolytescitations
- 2021Conjugated Microporous Polycarbazole-Sulfur Cathode Used in a Lithium-Sulfur Battery
- 2020In situ synchrotron XRD and sXAS studies on Li-S batteries with ionic-liquid and organic electrolytescitations
- 2019Electrochemically controlled deposition of ultrathin polymer electrolyte on complex microbattery electrode architecturescitations
- 2019Organic salts utilising the hexamethylguanidinium cation: the influence of the anion on the structural, physical and thermal propertiescitations
- 2018From Lithium Metal to High Energy Batteries
- 2018Integrating polymer electrolytes: A step closer to 3D-Microbatteries for MEMS
- 2017Electrochemistry of Lithium in Ionic Liquids - Working With and Without a Solid Electrolyte Interphase
- 2017A step closer to 3D-Microbatteries for sensors: integrating polymer electrolytes
- 2016Optimising the concentration of LiNO3 additive in C4mpyr-TFSI electrolyte-based Li-S batterycitations
- 2015S/PPy composite cathodes for Li-S batteries prepared by facile in-situ 2-step electropolymerisation process
- 2015Ionic transport through a composite structure of N-ethyl-N-methylpyrrolidinium tetrafluoroborate organic ionic plastic crystals reinforced with polymer nanofibrescitations
- 2013Extensive charge-discharge cycling of lithium metal electrodes achieved using ionic liquid electrolytescitations
- 2012Corrosion in amine post combustion capture plants
- 2010The influence of conductive additives and inter-particle voids in carbon EDLC electrodescitations
- 2010In situ NMR Observation of the Formation of Metallic Lithium Microstructures in Lithium Batteriescitations
- 2010Ionic Liquids with the Bis(fluorosulfonyl)imide (FSI) anion: Electrochemical properties and applications in battery technologycitations
Places of action
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document
From Lithium Metal to High Energy Batteries
Abstract
Lithium metal has the highest specific capacity of all electrode materials for batteries. It remains, largely, an unsolved mystery as to how to control Li plating in 2-dimensions for 100’s to 1000’s of cycles without the formation of dendrites which cause eventual short circuit and device failure. In order not to deal with the Li metal problem, significant interest has been poured into alternative high capacity anode materials such as silicon (Si) and composites thereof. As our knowledge of Si electrode technology increases, the benefits to energy density within the cell is incremental at best, returning us to the Li metal as a potential solution. However, the cost of Li metal has increased substantially in recent times due to the relative lack of supply and demand for Li precursors elsewhere in the battery value chain. Li metal is typically manufactured via the production of LiCl from a Li precursor, before being mixed with KCl. The eutectic mixture is then used in a Downes Cell to electrochemically produce Li metal, however, this process is both expensive and environmentally unfriendly. To address this problem, CSIRO has developed a new technology, LithSonicTM, to produce Li metal powder via carbothermal reduction which does not require the conversion of Li precursors to LiCl or the use of an electrochemical method. From this powder, we now have the opportunity to prepare Li foils where we have the potential to further engineer interfaces and attempt to control Li dendrites on cycling. One of the leading candidate next generation batteries is Li-Sulfur, however, in order to truly maximise its potential energy density, high sulfur loadings at the cathode are required. With high sulfur loadings come serious issues with polysulfide formation that can effect cycle life of the device [1]. We have undertaken X-ray diffraction and soft X-ray absorption spectroscopy to study crystalline and amorphous sulfur/polysulfides phases, respectively. The phase transitions between these species at different stages of cycling for lithium sulfur batteries based on organic and ionic liquid (IL) electrolytes are investigated in which IL-based cells show better capacity retention. Furthermore, the effect of the LiNO3 additive in the electrolyte is evaluated to identify the optimized concentration. In this presentation we will overview the carbothermal method for the production of Lithium metal, our work on the use of ionic liquid electrolytes to stabilise the metal interface, which is critical to enable devices such as Li-S, with the goal of developing the next generation of high energy batteries.