N-DOPED VERTICAL SILICON NANOWIRE ARRAYS AS THE ANODE FOR LITHIUM-ION BATTERY
Lithium-ion battery (LIB) is a type of secondary battery that has been scientifically and commercially proven for its high energy density as compared to the other type of secondary batteries. Currently, commercial LIB uses graphite as the anode, however, graphite anode exhibits moderate specific...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/49666 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Lithium-ion battery (LIB) is a type of secondary battery that has been
scientifically and commercially proven for its high energy density as compared
to the other type of secondary batteries. Currently, commercial LIB uses graphite
as the anode, however, graphite anode exhibits moderate specific capacity (372
mAhg-1) . On the other hand, silicon is one of the most promising substitutes
because it acquires a much higher energy density (4200 mAhg-1). Nonetheless,
silicon has poor intrinsic electrical conductivity and has a high risk of losing its
active material due to its large volume expansion (up to 420%) during reaction.
One of the ways to overcome this drawback is to transform the morphology of
silicon into nanowire and to improve the intrinsic property of silicon through
doping. Hence, there are still rooms to improve the manufacturing method of
silicon nanowire, especially on its arrangement on the anode of LIB.
In this report, n-doped vertical silicon nanowire arrays (V-SiNW) as the
anode for lithium ion battery and their effects of the novel arrangement were
studied. The n- and p-doped V-SiNW was fabricated using soft ultraviolet based
nanoimprint lithography and inductively coupled plasma dry reactive ion etching
at cryogenic temperature. The anode was characterized by XRD, SEM, EIS, and
four-point probe in order to initially identify its crystal structure, nano
morphology and resistivity, respectively. Then, lithium half-cell battery was
assembled using the chosen n-doped V-SiNW as its counter electrode of lithium
metal. The cell performance was examined using battery analyzer to know the
capacity and stability. The result showed that n-doped V-SiNW obtained a <100>
directional silicon and cylindrical shaped nanowire morphology with the
diameter of 2500 nm. The resistivity of V-SiNW through-thickness was 3 x 105
? cm, while the surface resistivity was 35 ? cm. The V-SiNW half-cell achieved
the capacity of 0.45 mAh/cm2 for 70 cycles at the current density of 0.06 mAcm-
2. As conclusion, the improved performance of uniquely fabricated V-SiNW is
due to the enhanced electron mobility route in the SiNW. Furthermore, the
arrayed spacing of the silicon anode serves as a buffer space for lithiation
expansion, resulting in the better stability of LIB.
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