FILM PREPARATION OF KAPPA-CARRAGEENAN (RED SEAWEED) BIOPOLYMER AS A NATURAL ELECTROLYTE IN ORGANIC BATTERY
The development of battery technology is currently quite rapid, especially in terms of improving performance by modifying the structure of the device or getting good material candidates, especially for its main components, namely electrolytes and electrodes. It is known that liquid and solid elec...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/81633 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The development of battery technology is currently quite rapid, especially in terms of
improving performance by modifying the structure of the device or getting good
material candidates, especially for its main components, namely electrolytes and
electrodes. It is known that liquid and solid electrolytes still dominate the types of
electrolytes that are currently developing. Liquid electrolytes are known to have a
large conductivity value but are flammable and have a high leakage rate. Meanwhile,
solid electrolytes are relatively safe with low conductivity values and are not
flammable. Currently, research on electrolyte materials has been carried out, one of
which is to make electrolytes from natural materials that have much potential as
organic materials with conductivity comparable to conventional electrolytes. One of
them is using kappa-carrageenan biopolymer which has been widely used as an
electronic component. However, the physical, mechanical, and chemical
characteristics of kappa-carrageenan have not been discussed in detail by researchers
to date.
The focus of this research is to study the preparation of kappa-carrageenan biopolymer
films, analyze the characteristics of biopolymer films, and study their opportunities as
electronic component materials, especially batteries. In this study, the biopolymer film
is projected as an electrolyte providing ions and cations through the addition of salt,
namely ammonium chloride (NH4Cl). In this study, the biopolymer film is projected as
an electrolyte providing ions and cations by adding salt, namely ammonium chloride
(NH4Cl). The quality of kappa carrageenan film was characterized through Scanning
Electron Microscopy (SEM), X-ray diffraction (XRD), Tensile Strength, and
conductivity tests using EIS. Opportunities as an electrolyte in the battery were tested
through charge and discharge characterization. Morphological test results show that
the surface of kappa-carrageenan when ammonium chloride (NH4Cl) is added is
smoother than the surface of pure kappa-carrageenan. XRD test results show that
kappa-carrageenan containing ammonium chloride (NH4Cl) is semi-crystalline and
has a high intensity with a peak around 2? = 32º. Investigation of the mechanical test results resulted in the flexibility of the film with KC and KC+NH4Cl showing the largest
tensile stress value is in the KC+20wt% NH4Cl sample which is 0.2 Mpa and the elastic
modulus in the KC+16.67wt% NH4Cl sample which is 2.94 Mpa greater than the KC
film which is 0.086 Mpa. The EIS test results for KC with the addition of NH4Cl showed
the highest film conductivity of 2.11 x 10-5 S/m, quite low compared to previous studies
which reached a conductivity of 4.53x10-5 S/m. The maximum voltage for organic
batteries with added salt is 3.1 V and 2.1 V for batteries without added salt through the
charging process. They then tested the performance of organic batteries by adding
loads in the form of LEDs and producing the highest current of 26.62 mA and the lowest
of 4.55 mA for about 16 minutes to 65 minutes in the discharge process.
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