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Sains Malaysiana 49(4)(2020): 871-876
http://dx.doi.org/10.17576/jsm-2020-4904-16
Enhancement of Non-Ohmic Properties of CoO DopeD ZnO Varistor
Ceramics using Soda Lime Silica (SLS) Glass (Peningkatan Sifat Bukan Ohmik Seramik Varistor CoO DopeD ZnO menggunakan Kaca Soda
Kapur Silika (SLS)) NUR QURATUL AINI ISMAIL, NOR KAMILAH SA'AT* & MOHD HAFIZ MOHD ZAID
Department of Physics, Faculty of Science, Universiti Putra Malaysia, 43400 UPM Serdang, Selangor Darul Ehsan, Malaysia
Diserahkan: 9 Oktober 2019/Diterima:
2 Januari 2020
ABSTRACT
ZnO-SLS-CoO (ZSC) based varistor ceramics
were prepared at a high sintering temperature of 1100 ºC via the conventional solid-state method. The
effect of SLS glass on the electrical properties was studied at the different
concentration of SLS glass ranging from 0.5 mol% to 2 mol%. Scanning electron
microscopy (SEM) and X-ray diffractometer (XRD) were used to examine
microstructure and crystal structure of the glass phase based ZSC varistor. For
the electrical characteristics, the source measuring unit was used. The result
shows that SiO2 as the major chemical compound found in the SLS
glass that responsible for controlling the ZnO grain
growth. When the concentration of SLS glass higher than 1 mol%, the dominant peak of ZnO was found in XRD pattern, which is the primary phase whereas the additional
peak belongs to Zn2SiO4 as the secondary phase. ZSC
varistor ceramics with 2 mol% of SLS glass possessed the best electrical
properties with the highest nonlinear coefficient α at 4.38 and the lowest leakage
current. The increasing value of α could be due to the increase in oxygen
vacancies that eventually contributes to the increase of Schottky barrier
formation.
Keywords: Nonlinear coefficient; Schottky barrier; solid-state method; varistors; zinc oxide
Seramik
varistor berasaskan ZnO-SLS-CoO (ZSC) disediakan pada suhu pensinteran tinggi 1100 ºC melalui kaedah keadaan
pepejal konvensional. Kesan kaca SLS terhadap sifat elektrik dikaji pada
kepekatan berbeza kaca SLS antara 0.5 mol% hingga 2 mol%.
Mikroskopi elektron imbasan (SEM) dan difraktometer sinar-X (XRD) digunakan
untuk memeriksa mikrostruktur dan struktur kristal fasa kaca berdasarkan varistor ZSC. Untuk ciri elektrik, unit pengukur sumber telah
digunakan. Hasilnya menunjukkan bahawa SiO2adalah sebatian kimia utama yang
terdapat di dalam kaca SLS yang bertanggungjawab
mengawal pertumbuhan bijirin ZnO. Apabila kepekatan kaca SLS lebih tinggi daripada
1 mol%, puncak ZnO yang dominan didapati dalam corak XRD, yang merupakan fasa
utama manakala puncak tambahan milik Zn2SiO4 sebagai fasa sekunder. Seramik varistor ZSC dengan 2
mol% kaca SLS memiliki sifat elektrik terbaik dengan pekali tak linear α tertinggi pada
4.38 dan arus kebocoran terendah. Peningkatan nilai α mungkin disebabkan
oleh peningkatan kekosongan oksigen yang akhirnya menyumbang kepada peningkatan
pembentukan halangan Schottky.
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