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Sains Malaysiana 47(9)(2018): 2091–2098 http://dx.doi.org/10.17576/jsm-2018-4709-17
Kesan Garam Litium Nitrat terhadap Sifat Elektrokimia Karboksimetil Kitosan (The Effect of Lithium Nitrate towards Electrochemical Properties
of Carboxymethyl Chitosan) N.N.
MOBARAK*,
F.N.
JANTAN,
N.A.
DZULKURNAIN,
A.
AHMAD
& M.P. ABDULLAH School of Chemical Sciences
and Food Technology, Faculty of Science and Technology, Universiti Kebangsaan Malaysia,
43600 UKM Bangi, Selangor Darul
Ehsan, Malaysia Received: 31 March 2018/Accepted:
17 May 2018 ABSTRAK Karboksimetil kitosan menunjukkan
potensi untuk
digunakan sebagai polimer induk bagi
aplikasi elektrolit
polimer pepejal. Kesan garam litium
nitrat terhadap sifat elektrokimia elektrolit polimer pepejal berasaskan karboksimetil kitosan telah dijalankan. Elektrolit polimer pepejal berasaskan karboksimetil kitosan disediakan melalui teknik pengacuan larutan dengan nisbah garam
litium nitrat
(LiNO3)
yang berbeza. Pencirian filem
telah dijalankan
dengan menggunakan spektroskopi inframerah transformasi Fourier-pantulan penuh kecil (ATR-FTIR)
dan Spektroskopi
Impedans Elektrokimia (EIS)
bagi penentuan
interaksi kimia dan sifat elektrokimia
polimer elektrolit
tersebut. Spektrum ATR-FTIR menunjukkan ion litium cenderung untuk berinteraksi dengan kumpulan karbonil dan kumpulan
ester dalam struktur
karboksimetil kitosan. Kekonduksian ion tertinggi yang
dicapai adalah 8.44 × 10-4
S cm-1 dengan
kepekatan garam
30 bt. % LiNO3 pada suhu bilik
dan 5.25 × 10-3 S
cm−1 pada
suhu 70°C. Filem karboksimetil kitosan-30% LiNO3 mencapai kestabilan secara elektrokimia sehingga 2.94 V. Keputusan kajian yang diperoleh menunjukkan elektrolit polimer pepejal berasaskan karboksimetil kitosan memberi satu tarikan baru
bagi aplikasi
bateri ion litium. Kata kunci: Elektrolit polimer pepejal; FTIR;
karboksimetil kitosan;
sifat elektrokimia ABSTRACT Carboxymethyl chitosan has showed its potential to be used as host polymer for
solid polymer electrolyte application. The effect of lithium
nitrate towards electrochemical properties of solid polymer
electrolyte based carboxymethyl chitosan has been investigated. Solid bio-polymer
electrolyte based carboxymethyl chitosan
was prepared by solution-casting technique with different ratios
of lithium nitrate (LiNO3) salt. The films were characterized
by attenuated total reflected Fourier transform infrared (ATR-FTIR)
Spectroscopy and Electrochemical Impedance Spectroscopy to determine
the chemical interaction and electrochemical properties of the
polymer electrolytes. Based on ATR-FTIR spectra, the lithium ions tend
to interact with carbonyl group and ether group in carboxymethyl
chitosan structure. The highest conductivity achieved was 8.44
× 10-4
S cm-1 with a concentration of 30 wt.
% of LiNO3 salt at room temperature and
5.25 × 10-3 S cm−1 at
70°C. The films were electrochemically stable up to 2.94 V.
The results suggest that this solid polymer electrolyte based
on carboxymethyl chitosan demonstrate
potential to be applied in lithium ion batteries. Keywords: Carboxymethyl chitosan; electrochemical
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