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particles still has diameters less than 100 nm
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ZnO 2
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particles still has diameters less than 100 nm. The size distribution of these nanoparticles is shown in Figure(6), The distribution seems to be symmetric about 22 nm, The particles of sizesis in the range of 5 - 45 nm in diameter for this specimen. Fig.6. the particle-size distribution of the nano-sized ZnO 3.3. Electrical measurement The Electrical characteristic (I-V)was measuredby using V-I source/ measuring unit(MEGOHMMETER-M1500P (1500 V,20 mA)),an Ampere meter and a Voltmeter. A summary of the electrical properties was listed in Table2. The breakdown voltage was measured at V(1mA) and the leakage current (I L ) was measured at 0.75V(1mA). The non-linearity coefficient defined by empirical formula: I=KV α .................................................................(2) Where I is the current, V is the applied electric Voltage; α is the nonlinearity coefficient and K is constant. howeverNon-linearity coefficient determined by the formula: ) 1 log 2 /(log ) 1 log 2 (log V V I I ..............(3) Khalaf AL ABDULLAH, Sahar AWDE/ Energy Procedia 00 (2017) 000–000 5 and it is identified in the range of 1.0 mA to 10 mA. Where V1 and V2 are the electric voltage at I1=1 mA and I2=10 mA, respectively. The voltage gradient E(1mA) is calculated by E(1mA)= V(1mA)/h, where h is the sample thickness. The breakdown voltage per grain boundary (Vgb), given by the equation (Anas et al. 2010): E = Vgb/d, where d is the average of grain size[14-16], and equal to 4um in this study after sintering. Table 2. Summary of the electrical properties of pure ZnO Varistor. Nonlinearity coefficient(α) Breakdown Voltage Voltage(V) gradient(V/mm) Leakage current (I L ) (uA) The breakdown voltage per grain boundary (Vgb) (V) 30 450 225 100 0.9 Figure (7) shows the current as a function of the electric voltage for theSample. The curve can be divided into two regions: the first one (the ohmic region) is known as a high resistance region and the second one (the non-ohmic region) is known as a very low resistance region. The electrical properties (breakdown voltage, non-linear coefficient,etc) are typically related to grain size. A smaller grain size can effectively increase nonlinearity coefficient α and the breakdown voltage because the number of grain boundaries per unit thickness of varistor increases[16]. Fig.7.( I-V) characteristic of pureZnO Varistor prepared at 1050 o C Fig.8. (I-V) Experimental characteristics of pure ZnO Varistor at various temperatures 570 Khalaf AL ABDULLAH et al. / Energy Procedia 119 (2017) 565–570 6 Khalaf AL ABDULLAH, Sahar AWDE/ Energy Procedia 00 (2017) 000–000 The varistor essentially needs the leakage current to be as low as possible to avoid the heating of the material during the use. The heating causes the degradation of the varistor because the migration of Zn to the grain boundary, and the depletion layer formed at the grain boundary. We measured the I-V characteristics of sample at various temperatures to explore the effect of varying temperature on electrical properties on nano ZnO-based varistors as shown in Figure (8).It is clear from the figure, that the leakage current, in the low voltage region (linear zone characterized by a highresistivity, ρ=1010Ω.cm)increases with temperature. It is also observable that the current is strongly dependent on the electric voltage strength in the nonlinear zone, above 450V(breakdown voltage).However, the doping of ZnO with some Nano powders metal oxides offers high electrical properties of ZnO varistors. Download 119.6 Kb. Do'stlaringiz bilan baham: 
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