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Sains Malaysiana 42(8)(2013):
1139–1144
Microstructural and Nonlinear Electrical
Properties of ZnO Ceramics with Small
Amount of MnO2 Dopant
(Sifat Mikrostruktur dan Elektrik
Tak-linear Seramik ZnO dengan
Kuantiti Kecil Dopan MnO2)
A.N. Fauzana, B.Z. Azmi* &
M.G.M. Sabri
Department of Physics, Faculty of Science,
Universiti Putra Malaysia, 43400 UPM Serdang, Selangor, D.E. Malaysia
W.R. Wan Abdullah & M. Hashim
Materials Synthesis and Characterization
Laboratory, Institute of Advanced Technology
Universiti Putra Malaysia, 43400 UPM
Serdang, Selangor D.E. Malaysia
Received: 27 June 2012 /Accepted: 16
December 2012
ABSTRACT
A small amount of MnO2 dopant was added to ZnO system to
see the improvement of the ceramic varistor microstructural and nonlinear
electrical properties. The samples were prepared using solid-state reaction method
and the microstructure and nonlinear electrical properties of the ZnO-xMnO2 system were investigated for × = 0.011 to 0.026 mol%, at
three sintering temperatures, 1180°C, 1240°C and 1300°C for 1 and 2 h sintering
time. The XRD and EDAX analyses showed that the main phase was ZnO while ZnMnO3 and ZnMnO7 as
the secondary phases developed and distributed at the grain boundaries and
triple point junction. The SEM observation
revealed that prolonged sintering temperature and time improved the microstructure
uniformity and strongly influences the nonlinear behavior of the samples. The
maximum density and grain size have been observed at 92% of theoretical density
and 10.8 μm, respectively and occur at the highest sintering temperature
which is 1300°C. The value of nonlinear coefficient α is found to increase
with the increase of MnO2 doping
level up to 0.016 mol% and drop with further doping level increment for all sintering
temperatures and time.
Keywords: MnO2;
nonlinear coefficient; ZnO varistor
ABSTRAK
Kuantiti kecil bahan dop MnO2 ditambah kepada sistem ZnO untuk melihat peningkatan sifat-sifat
mikrostruktur dan keelektrikan tak-linear seramik varistor. Sampel telah
disediakan melalui kaedah tindak balas keadaan pepejal dan ciri-ciri
struktur-mikro dan elektrik tak-linear bagi sistem ZnO-xMnO2 telah dijalankan untuk kuantiti
kecil × = 0.011 sehingga 0.026 mol%, pada tiga suhu pensinteran, 1180°C,
1240°C dan 1300ºC dengan masa pensinteran 1 dan 2 jam. Analisis XRD dan EDAX menunjukkan
bahawa fasa utama adalah ZnO manakala ZnMnO3 dan ZnMnO7 sebagai fasa kedua terbentuk dan
tertabur di sempadan butiran dan titik simpang tiga. Pemerhatian melalui SEM menunjukkan bahawa pemanjangan
suhu dan masa persinteran memperbaiki keseragaman mikrostruktur dan
mempengaruhi kelakuan tak-linear sampel. Ketumpatan dan saiz butiran maksimum
telah diperhatikan pada 92% daripada ketumpatan teori dan 10.8.μm,
masing-masing, berlaku pada suhu pensinteran tertinggi iaitu 1300ºC. Nilai
daripada pekali tak-linear α didapati meningkat dengan peningkatan paras
dop MnO2 sehingga tahap
0.016 mol% dan menurun dengan penambahan paras dop seterusnya untuk semua suhu
dan masa pensinteran.
Kata
kunci: MnO2;
Pekali tak-linear; varistor ZnO
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*Corresponding author; email: azmizak@gmail.com
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