ANODA SILIKON BERPORI DARI PROSES BALL MILL UNTUK BATERAI ION-LITIUM
Lithium-ion battery is a secondary battery that is widely used on electronic gadgets and electric vehicles due to its high energy density compared to other secondary batteries. Lithium-ion batteries commonly use a graphite-based anode that has limited maximum specific capacity at 372 mAh/g. There ar...
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id-itb.:574382021-08-23T09:21:10ZANODA SILIKON BERPORI DARI PROSES BALL MILL UNTUK BATERAI ION-LITIUM Yosia Edward Koraag, Pierre Indonesia Final Project ball-milling, silicon anode, porous structure, lithium-ion battery INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/57438 Lithium-ion battery is a secondary battery that is widely used on electronic gadgets and electric vehicles due to its high energy density compared to other secondary batteries. Lithium-ion batteries commonly use a graphite-based anode that has limited maximum specific capacity at 372 mAh/g. There are several ways to increase lithium-ion battery capacity, such as using silicon as the anode material, which has high specific capacity up to 4200 mAh/g. However, silicon has several drawbacks, such as low electrical conductivity, and massive volume expansion that can decrease the performance of the lithium-ion battery. Hence, strategies are developed to engineer the structure and composition of silicon to produce high-performance anodes. In this research, the silicon anode is synthesized by utilizing ball-milling and alkaline etching. As confirmed by SEM/TEM and BET surface area analysis, the as-produced silicon has an average size of 3 microns and a porous structure. From XRD data, there is a formation of amorphous silica on the porous silicon particle. Half-cell Li-ion batteries using porous silicon anode are assembled to determine the capacity and cycling stability of the ball-milled porous silicon anode. Despite the promising morphology, ball-milled porous silicon anode has a lower capacity than ball-milled silicon anode (without etching). This poor performance shows that creating a porous structure is not enough to increase the performance of silicon anode, and further processing is needed to improve its performance. text |
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Lithium-ion battery is a secondary battery that is widely used on electronic gadgets and electric vehicles due to its high energy density compared to other secondary batteries. Lithium-ion batteries commonly use a graphite-based anode that has limited maximum specific capacity at 372 mAh/g. There are several ways to increase lithium-ion battery capacity, such as using silicon as the anode material, which has high specific capacity up to 4200 mAh/g. However, silicon has several drawbacks, such as low electrical conductivity, and massive volume expansion that can decrease the performance of the lithium-ion battery. Hence, strategies are developed to engineer the structure and composition of silicon to produce high-performance anodes.
In this research, the silicon anode is synthesized by utilizing ball-milling and alkaline etching. As confirmed by SEM/TEM and BET surface area analysis, the as-produced silicon has an average size of 3 microns and a porous structure. From XRD data, there is a formation of amorphous silica on the porous silicon particle. Half-cell Li-ion batteries using porous silicon anode are assembled to determine the capacity and cycling stability of the ball-milled porous silicon anode. Despite the promising morphology, ball-milled porous silicon anode has a lower capacity than ball-milled silicon anode (without etching). This poor performance shows that creating a porous structure is not enough to increase the performance of silicon anode, and further processing is needed to improve its performance.
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| format |
Final Project |
| author |
Yosia Edward Koraag, Pierre |
| spellingShingle |
Yosia Edward Koraag, Pierre ANODA SILIKON BERPORI DARI PROSES BALL MILL UNTUK BATERAI ION-LITIUM |
| author_facet |
Yosia Edward Koraag, Pierre |
| author_sort |
Yosia Edward Koraag, Pierre |
| title |
ANODA SILIKON BERPORI DARI PROSES BALL MILL UNTUK BATERAI ION-LITIUM |
| title_short |
ANODA SILIKON BERPORI DARI PROSES BALL MILL UNTUK BATERAI ION-LITIUM |
| title_full |
ANODA SILIKON BERPORI DARI PROSES BALL MILL UNTUK BATERAI ION-LITIUM |
| title_fullStr |
ANODA SILIKON BERPORI DARI PROSES BALL MILL UNTUK BATERAI ION-LITIUM |
| title_full_unstemmed |
ANODA SILIKON BERPORI DARI PROSES BALL MILL UNTUK BATERAI ION-LITIUM |
| title_sort |
anoda silikon berpori dari proses ball mill untuk baterai ion-litium |
| url |
https://digilib.itb.ac.id/gdl/view/57438 |
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1822002645835972608 |