THE IMPACT OF EXFOLIATED-GRAPHENE (EG) AS AN ADDITIONAL CONDUCTIVE MATERIAL ON LINI0.5MN1.5O4 (LNMO) CATHODE MATERIAL OF LITIUM-ION BATTERIES
LiNi0,5Mn1,5O4 (LNMO) is a promising cathode material for fast charging in lithium-ion battery technology. LNMO structure contains a three-dimensional lithium-ion diffusion path, thereby accelerating the movement of litium ions during the intercalation and deintercalation processes. Then, LNMO ha...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/70494 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | LiNi0,5Mn1,5O4 (LNMO) is a promising cathode material for fast charging in
lithium-ion battery technology. LNMO structure contains a three-dimensional
lithium-ion diffusion path, thereby accelerating the movement of litium ions during
the intercalation and deintercalation processes. Then, LNMO has an energy density
of up to 650 Wh kg-1
and a high working voltage (4.7 V), so it is potential to be
applied to electric vehicles. In addition, LNMO does not contain cobalt, which is
harmless to the environment and superior in terms of economy. However, LNMO
has several drawbacks, namely Jahn-Teller distortion, which makes the crystal
structure of LNMO unstable, and electrolyte decomposition at high voltage causes
the formation of a thick cathode electrolyte interphase (CEI) which can reduce
conductivity. The addition of material to LNMO is an effective strategy to protect
particles from electrolyte attack. However, the material must be conductive to
facilitate the charge transfer. This research reports on LNMO synthesis using the
coprecipitation method and studies the effect of adding graphene-based materials,
such as exfoliated-graphene (EG) with varying mass percentages, to improve the
electrochemical performance of LNMO cathode materials in lithium-ion battery
applications. The results of X-Ray Diffraction (XRD) characterization show the
XRD pattern of LNMO material with a crystal structure of Fd3?m. The impurity
phases are detected at 37.4° and 43.7° of LixNi1-xO; meanwhile, Na0.7MnO2.05 is at
37.4°. Then, the comparison of the XRD patterns between LNMO and LNMO
materials that have been mixed with EG (LNMO-EG) has a difference of 26.5°. The
intensity at the peak of 26.5o
is clearly visible with the addition of the mass
percentage of EG material which confirms the existence of EG in the modified
LNMO material. The particle morphology of the LNMO and LNMO-EG materials
has the same shape: truncated octahedral and 1-2 µm in size. A truncated
octahedral morphology which indicates the presence of three planes, such as (111)
and (100), supports the LNMO material to produce an excellent electrochemical
performance that is because each plane has a role in stability (111) and ionic
conductivity (100). The existence of EG is detected as graphene sheets which
connecting each LNMO particles. Then, in the LNMO-EG, it can be seen that there
is EG material in the form of sheets that connect the LNMO particles. The strategy
can improve the electronic conductivity and protect the LNMO particles from
electrolyte attack. Electrochemical Impedance Spectroscopy (EIS) test results
confirmed the lower Rct value due to the addition of EG material. Based on the
charge-discharge test in the first cycle at 0.1 C, it confirmed that the crystal structure of the LNMO formed by Fd3?m was due to the redox reaction of
Mn3+/Mn4+ around 4.0 V. On other hand, the addition of EG with a low percentage
was considered less effective, but when EG is too high, it will inhibit the movement
of Li+
ions. This was confirmed through the electrochemical performance of the
LNMO material in the rate capability and cycle stability tests. According to the test
results, LNMO 5% EG has optimum performance with a specific discharge capacity
of 93.67 mAh g-1 at 5 C and capacity retention of 95.22% after 100 cycles at 1 C. |
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