ELECTROLYTE POLYMER MEMBRANES BASED ON CHITOSAN/LIOH/SUCCINIC ACID CROSSLINKER FOR LITHIUM - ION BATTERY APPLICATION
Batteries are an important component in building electronic devices. Batteries that are currently widely used in electronic devices are lithium-ion batteries, because they are environmentally friendly. However, the main constituent component of lithium-ion batteries has been a liquid electrolyte,...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/71560 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Batteries are an important component in building electronic devices. Batteries that
are currently widely used in electronic devices are lithium-ion batteries, because
they are environmentally friendly. However, the main constituent component of
lithium-ion batteries has been a liquid electrolyte, for example lithium-sulfur, which
is risky and dangerous in use. Therefore, it is necessary to develop alternatives to
the liquid electrolyte. Many developments have been carried out, namely through
the formation of solid electrolytes with a thin and environmentally friendly form.
Modifications that have been developed to date are the formation of solid
electrolytes based on polymers that are environmentally friendly and derived from
natural materials, one of which is using chitosan-based polymers. However, this
pure chitosan-based solid electrolyte biopolymer still has weaknesses, namely ionic
conductivity/conduction and mechanical properties that are still relatively low.
Therefore, other modifications are needed related to chitosan-based solid
electrolyte polymers, one of which is through the addition of lithium salts in the
form of LiOH compounds and crosslinking agents in the form of succinic acid to
improve the ionic conductivity/conduction and mechanical properties of chitosanbased membranes. The method used in the formation of solid electrolyte polymers
is solution casting. The characterization of the isolated chitosan in this study
includes characterization of functional groups with FTIR, analysis of the degree of
deacetylation, and determination of molecular weight with a viscometer. The
isolated chitosan is used as a base material for the formation of electrolyte polymer
membranes. The chitosan/LiOH-based electrolyte polymer membrane/succinic
acid crosslinker was successfully synthesized by dissolving the
chitosan/LiOH/succinic acid mixture with 2% (v/v) acetic acid solvent through
stirring for 28 hours at room temperature, then drying at room temperature for 24
hours, and continued oven drying at 35? for 13.5 hours. Furthermore, chitosan
based electrolyte polymer membranes and their composites were determined under
optimum conditions through functional group characterization with FTIR, swelling
degree, mechanical properties test, and ionic conductivity/conduction test. The
chitosan-based polymer electrolyte membranes and their composites with optimum
conditions were further characterized through XRD diffraction pattern analysis surface morphology and cross-section with SEM, and thermal stability test with
TG/DTA. The results showed that the successfully isolated chitosan amounted to
17.84 grams with a deacetylation degree of 76.86% and a molecular weight of
10.86×10-5 grams/mol. Membranes with optimum conditions gave tensile strength
and strain values of 31.23 MPa and 68.5% and ionic conductivity/conduction of
2.95×10-5 S/cm obtained from membranes with a composition of 78% (m/m)
chitosan, 4% (m/m) succinic acid and 18% (m/m) LiOH. The
chitosan/LiOH/succinic acid membrane provides a degree of crystallinity of
59.67% with a rough and hollow surface morphology,and has a thermal resistance
of up to 356?. From these results it can be concluded that the chitosan/LiOH
membrane / succinic acid crosslinker has the potential to be used as a solid
electrolyte in lithium-ion battery applications. |
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