Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan

The majority of all polymers are insulators; hence do not show any remarkable electro activity. Researchers have found out how to obtain conducting polymers by the introduction of salts, plasticizer and nanofillers. Uniform dispersion of plasticizer and fillers in salt-polymer matrices creates a cla...

Full description

Saved in:
Bibliographic Details
Main Authors: Ahmad, Azizah Hanom, Zulkefli, Fatin Nabella, Nor Hasnan, Aisyah
Format: Book Section
Language:English
Published: Research Innovation Business Unit 2014
Subjects:
Online Access:https://ir.uitm.edu.my/id/eprint/82252/1/82252.pdf
https://ir.uitm.edu.my/id/eprint/82252/
Tags: Add Tag
No Tags, Be the first to tag this record!
id my.uitm.ir.82252
record_format eprints
institution Universiti Teknologi Mara
building Tun Abdul Razak Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Mara
content_source UiTM Institutional Repository
url_provider http://ir.uitm.edu.my/
language English
topic Metal oxide semiconductors
spellingShingle Metal oxide semiconductors
Ahmad, Azizah Hanom
Zulkefli, Fatin Nabella
Nor Hasnan, Aisyah
Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan
description The majority of all polymers are insulators; hence do not show any remarkable electro activity. Researchers have found out how to obtain conducting polymers by the introduction of salts, plasticizer and nanofillers. Uniform dispersion of plasticizer and fillers in salt-polymer matrices creates a class of novel materials exhibiting superior electrical and mechanical properties which is suitable to replace many existing materials such as those for engineering applications and in electrochemical devices. Novel material consists of starch is one of the most common renewable and biodegradable polymers deposited as granule in plants which can be found abundantly in our country. It is composed of repeating amylose and amylopectin. Materials: In this research work, potato starch was chosen to be the polymer host because it has better morphology in comparison to other starch. Physically, it appeared to be soft flexible film with high conductivity compared to corn starch. Furthermore, instead of just being a main food item, potato starch is presently applied in the industrial field as coatings and sizing in paper, textiles and carpets as binders and adhesives, absorbents and encapsulates. Starch based film is reported to exhibit good mechanical properties. In addition, the dry thin film of starch could also be prepared easily. Ammonium salt was chosen because it does not have high tendency to break the starch. Method: The thin clear films of potato starch were prepared by solution casting technique. A certain amount of potato starch (Sigma-Aldrich) was weighed and dissolved into 50ml of acetic acid (Systerm) in a 100mL beaker and left to be stirred for 20 minutes at a certain temperature. Once the cloudy solution turns clear and it is cooled to room temperature. The solution is then doped with various amounts of ammonium salts. Later, these dry thin films were characterized via Impedance Spectroscopy, Fourier Transform Infrared (FTIR), X-Ray Diffraction (XRD), and Scanning Electron Microscope (SEM). Results: Based on the impedance results, the conductivity of starch is low due to no mobile ions provided within the sample. The incorporation of salt has increased the conductivity gradually. The higher the concentration of the ammonium salt, it actually attributed to increase in number density of mobile ions. The number density of charge carriers’ increase since the rate of ion dissociation is greater than the rate of ion association. But if the salt concentration is too high, it could increase the influence of the ion pairs and higher ion aggregation, which can reduces the overall mobility and degree of freedom hence decreases the conductivity. FTIR measurement was used to determine the interactions between salt and the polymer host. In the present work, FTIR spectroscopy was recorded using Spotlight 400 Perkin-Elmer spectrometer in the wavenumber range of 450-4000 cm_1. The FTIR spectra indicates that the complexation between starch and ammonium salt has occurred. Upon higher concentration of the salt, hydroxyl band shifted to higher wavenumber, this may be due to the fact that either the excess salt did not dissociate or the ions recombine to form a neutral ion pair which decreases the number of ions. From the x-ray diffractogram, three crystalline peaks are observed thus indicates the pure starch film shows semi crystalline state due to the presence of both sharp and diffuse diffraction peaks. The fraction of amorphous phase and the charge carriers increase simultaneously with increasing ion concentration. The optimum composition of the green solid electrolyte has the potential to be used as solid electrolyte in electrical devices since it shows maximum conductivity of 10-3 and serve as an ionic conductor.
format Book Section
author Ahmad, Azizah Hanom
Zulkefli, Fatin Nabella
Nor Hasnan, Aisyah
author_facet Ahmad, Azizah Hanom
Zulkefli, Fatin Nabella
Nor Hasnan, Aisyah
author_sort Ahmad, Azizah Hanom
title Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan
title_short Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan
title_full Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan
title_fullStr Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan
title_full_unstemmed Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan
title_sort green solid electrolyte for electrochemical devices / azizah hanom ahmad, fatin nabella zulkefli and aisyah nor hasnan
publisher Research Innovation Business Unit
publishDate 2014
url https://ir.uitm.edu.my/id/eprint/82252/1/82252.pdf
https://ir.uitm.edu.my/id/eprint/82252/
_version_ 1779442779284307968
spelling my.uitm.ir.822522023-09-27T04:15:16Z https://ir.uitm.edu.my/id/eprint/82252/ Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan Ahmad, Azizah Hanom Zulkefli, Fatin Nabella Nor Hasnan, Aisyah Metal oxide semiconductors The majority of all polymers are insulators; hence do not show any remarkable electro activity. Researchers have found out how to obtain conducting polymers by the introduction of salts, plasticizer and nanofillers. Uniform dispersion of plasticizer and fillers in salt-polymer matrices creates a class of novel materials exhibiting superior electrical and mechanical properties which is suitable to replace many existing materials such as those for engineering applications and in electrochemical devices. Novel material consists of starch is one of the most common renewable and biodegradable polymers deposited as granule in plants which can be found abundantly in our country. It is composed of repeating amylose and amylopectin. Materials: In this research work, potato starch was chosen to be the polymer host because it has better morphology in comparison to other starch. Physically, it appeared to be soft flexible film with high conductivity compared to corn starch. Furthermore, instead of just being a main food item, potato starch is presently applied in the industrial field as coatings and sizing in paper, textiles and carpets as binders and adhesives, absorbents and encapsulates. Starch based film is reported to exhibit good mechanical properties. In addition, the dry thin film of starch could also be prepared easily. Ammonium salt was chosen because it does not have high tendency to break the starch. Method: The thin clear films of potato starch were prepared by solution casting technique. A certain amount of potato starch (Sigma-Aldrich) was weighed and dissolved into 50ml of acetic acid (Systerm) in a 100mL beaker and left to be stirred for 20 minutes at a certain temperature. Once the cloudy solution turns clear and it is cooled to room temperature. The solution is then doped with various amounts of ammonium salts. Later, these dry thin films were characterized via Impedance Spectroscopy, Fourier Transform Infrared (FTIR), X-Ray Diffraction (XRD), and Scanning Electron Microscope (SEM). Results: Based on the impedance results, the conductivity of starch is low due to no mobile ions provided within the sample. The incorporation of salt has increased the conductivity gradually. The higher the concentration of the ammonium salt, it actually attributed to increase in number density of mobile ions. The number density of charge carriers’ increase since the rate of ion dissociation is greater than the rate of ion association. But if the salt concentration is too high, it could increase the influence of the ion pairs and higher ion aggregation, which can reduces the overall mobility and degree of freedom hence decreases the conductivity. FTIR measurement was used to determine the interactions between salt and the polymer host. In the present work, FTIR spectroscopy was recorded using Spotlight 400 Perkin-Elmer spectrometer in the wavenumber range of 450-4000 cm_1. The FTIR spectra indicates that the complexation between starch and ammonium salt has occurred. Upon higher concentration of the salt, hydroxyl band shifted to higher wavenumber, this may be due to the fact that either the excess salt did not dissociate or the ions recombine to form a neutral ion pair which decreases the number of ions. From the x-ray diffractogram, three crystalline peaks are observed thus indicates the pure starch film shows semi crystalline state due to the presence of both sharp and diffuse diffraction peaks. The fraction of amorphous phase and the charge carriers increase simultaneously with increasing ion concentration. The optimum composition of the green solid electrolyte has the potential to be used as solid electrolyte in electrical devices since it shows maximum conductivity of 10-3 and serve as an ionic conductor. Research Innovation Business Unit 2014 Book Section NonPeerReviewed text en https://ir.uitm.edu.my/id/eprint/82252/1/82252.pdf Green solid electrolyte for electrochemical devices / Azizah Hanom Ahmad, Fatin Nabella Zulkefli and Aisyah Nor Hasnan. (2014) In: IIDEX 2014: invention, innovation & design exposition. Research Innovation Business Unit, Shah Alam, Selangor, p. 136. (Submitted)
score 13.211869