Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate
Due to the increasing demand for improved energy storage devices to enable renewable energy sources, there has been great demand for improved batteries. One possible avenue for improved batteries with performance beyond that of conventional lithium-ion batteries is the lithium-sulfur system. This...
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sg-ntu-dr.10356-1604782023-11-27T07:49:02Z Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate Ong, Samuel Jun Hoong Xu Zhichuan, Jason School of Materials Science and Engineering xuzc@ntu.edu.sg Engineering::Materials::Energy materials Science::Chemistry::Physical chemistry::Electrochemistry Due to the increasing demand for improved energy storage devices to enable renewable energy sources, there has been great demand for improved batteries. One possible avenue for improved batteries with performance beyond that of conventional lithium-ion batteries is the lithium-sulfur system. This battery chemistry allows for significantly greater specific capacity using more abundant materials than those in conventional lithium batteries, but they face several issues. These issues include poor conductivity, volume expansion, the polysulfide shuttle effect, and poor rate capability. To overcome these issues, one possible approach is the use of electrocatalysts and polysulfide adsorbers in the cathode to alleviate polysulfide flooding and accelerate reaction kinetics. This is often combined with the ubiquitous additive lithium nitrate in the electrolyte as an anti-shuttle agent. However, despite significant attention from the research community, the mechanism behind many of these catalysts remains poorly understood. Furthermore, the possibility of adverse or beneficial interactions of such catalysts with electrolyte additives remains unexplored. This thesis, therefore, aims to examine the relationship between the physical and electronic properties of spinel metal oxides, a highly flexible class of material, with their catalytic and polysulfide adsorbing properties in typical lithium-sulfur cells. Towards this end, a polysulfide adsorber, magnesium ferrite, was tested in combination with the common electrolyte additive lithium nitrate. The two beneficial components interfered with each other, with greatest effect at high charge/discharge rate and high lithium nitrate concentrations. Therefore, lithium nitrate concentrations were kept low for the next study examining various spinel ferrites as lithiumsulfur catalysts. The results of this study suggest that their catalytic performance may be described using their metal-oxygen bond covalency. Greater covalency was found to be beneficial up to a limit, beyond which more covalent character was detrimental. This was followed by an examination of the effects of metal coordination site on catalytic performance. Composition and annealing temperature could be used to tune the site occupation of iron and cobalt between tetrahedral and octahedral sites in zinc-substituted magnetite and cobalt aluminate. The results indicated that tetrahedral site occupation is beneficial for catalytic performance. These established relationships will be useful in the future design of more effective lithium-sulfur catalysts and polysulfide adsorbers. Doctor of Philosophy 2022-07-25T06:21:15Z 2022-07-25T06:21:15Z 2022 Thesis-Doctor of Philosophy Ong, S. J. H. (2022). Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/160478 https://hdl.handle.net/10356/160478 10.32657/10356/160478 en This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). application/pdf Nanyang Technological University |
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Engineering::Materials::Energy materials Science::Chemistry::Physical chemistry::Electrochemistry Ong, Samuel Jun Hoong Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate |
| description |
Due to the increasing demand for improved energy storage devices to enable
renewable energy sources, there has been great demand for improved batteries.
One possible avenue for improved batteries with performance beyond that of
conventional lithium-ion batteries is the lithium-sulfur system. This battery
chemistry allows for significantly greater specific capacity using more abundant
materials than those in conventional lithium batteries, but they face several
issues. These issues include poor conductivity, volume expansion, the
polysulfide shuttle effect, and poor rate capability. To overcome these issues,
one possible approach is the use of electrocatalysts and polysulfide adsorbers in
the cathode to alleviate polysulfide flooding and accelerate reaction kinetics.
This is often combined with the ubiquitous additive lithium nitrate in the
electrolyte as an anti-shuttle agent.
However, despite significant attention from the research community, the
mechanism behind many of these catalysts remains poorly understood.
Furthermore, the possibility of adverse or beneficial interactions of such
catalysts with electrolyte additives remains unexplored. This thesis, therefore,
aims to examine the relationship between the physical and electronic properties
of spinel metal oxides, a highly flexible class of material, with their catalytic and
polysulfide adsorbing properties in typical lithium-sulfur cells. Towards this end,
a polysulfide adsorber, magnesium ferrite, was tested in combination with the
common electrolyte additive lithium nitrate. The two beneficial components
interfered with each other, with greatest effect at high charge/discharge rate and
high lithium nitrate concentrations. Therefore, lithium nitrate concentrations
were kept low for the next study examining various spinel ferrites as lithiumsulfur catalysts. The results of this study suggest that their catalytic performance
may be described using their metal-oxygen bond covalency. Greater covalency
was found to be beneficial up to a limit, beyond which more covalent character
was detrimental. This was followed by an examination of the effects of metal
coordination site on catalytic performance. Composition and annealing
temperature could be used to tune the site occupation of iron and cobalt between tetrahedral and octahedral sites in zinc-substituted magnetite and cobalt
aluminate. The results indicated that tetrahedral site occupation is beneficial for
catalytic performance. These established relationships will be useful in the future
design of more effective lithium-sulfur catalysts and polysulfide adsorbers. |
| author2 |
Xu Zhichuan, Jason |
| author_facet |
Xu Zhichuan, Jason Ong, Samuel Jun Hoong |
| format |
Thesis-Doctor of Philosophy |
| author |
Ong, Samuel Jun Hoong |
| author_sort |
Ong, Samuel Jun Hoong |
| title |
Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate |
| title_short |
Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate |
| title_full |
Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate |
| title_fullStr |
Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate |
| title_full_unstemmed |
Spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate |
| title_sort |
spinel oxides in lithium-sulfur: catalysis and interaction with lithium nitrate |
| publisher |
Nanyang Technological University |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160478 |
| _version_ |
1783955604299055104 |