优化Bi2O3和TiO2以实现ZnO低压压敏电阻的最大非线性电学性能。

Optimizing Bi2O3 and TiO2 to achieve the maximum non-linear electrical property of ZnO low voltage varistor.

作者信息

Abdollahi Yadollah, Zakaria Azmi, Aziz Raba'ah Syahidah, Tamili Siti Norazilah Ahmad, Matori Khamirul Amin, Shahrani Nuraine Mariana Mohd, Sidek Nurhidayati Mohd, Dorraj Masoumeh, Moosavi Seyedehmaryam

机构信息

Material Synthesis and Characterization Laboratory, Institute of Advanced Technology, Universiti Putra Malaysia, 43400 UPM, Serdang, Selangor, Malaysia.

Department of Physics, Faculty Science, Universiti Putra Malaysia, 43400 UPM, Serdang, Selangor, Malaysia.

出版信息

Chem Cent J. 2013 Aug 10;7:137. doi: 10.1186/1752-153X-7-137. eCollection 2013.

DOI:10.1186/1752-153X-7-137

PMID:23938168

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3751521/

Abstract

BACKGROUND

In fabrication of ZnO-based low voltage varistor, Bi2O3 and TiO2 have been used as former and grain growth enhancer factors respectively. Therefore, the molar ratio of the factors is quit important in the fabrication. In this paper, modeling and optimization of Bi2O3 and TiO2 was carried out by response surface methodology to achieve maximized electrical properties. The fabrication was planned by central composite design using two variables and one response. To obtain actual responses, the design was performed in laboratory by the conventional methods of ceramics fabrication. The actual responses were fitted into a valid second order algebraic polynomial equation. Then the quadratic model was suggested by response surface methodology. The model was validated by analysis of variance which provided several evidences such as high F-value (153.6), very low P-value (<0.0001), adjusted R-squared (0.985) and predicted R-squared (0.947). Moreover, the lack of fit was not significant which means the model was significant.

RESULTS

The model tracked the optimum of the additives in the design by using three dimension surface plots. In the optimum condition, the molars ratio of Bi2O3 and TiO2 were obtained in a surface area around 1.25 point that maximized the nonlinear coefficient around 20 point. Moreover, the model predicted the optimum amount of the additives in desirable condition. In this case, the condition included minimum standard error (0.35) and maximum nonlinearity (20.03), while molar ratio of Bi2O3 (1.24 mol%) and TiO2 (1.27 mol%) was in range. The condition as a solution was tested by further experiments for confirmation. As the experimental results showed, the obtained value of the non-linearity, 21.6, was quite close to the predicted model.

CONCLUSION

Response surface methodology has been successful for modeling and optimizing the additives such as Bi2O3 and TiO2 of ZnO-based low voltage varistor to achieve maximized non-linearity properties.

摘要

背景

在基于氧化锌的低压压敏电阻制造中，Bi₂O₃和TiO₂分别用作前驱体和晶粒生长增强因子。因此，这些因子的摩尔比在制造过程中非常重要。本文采用响应面法对Bi₂O₃和TiO₂进行建模与优化，以实现电学性能最大化。通过中心复合设计，利用两个变量和一个响应量来规划制造过程。为获得实际响应，在实验室采用传统陶瓷制造方法进行设计。将实际响应拟合到一个有效的二阶代数多项式方程中。然后通过响应面法提出二次模型。通过方差分析对模型进行验证，方差分析提供了几个证据，如高F值（153.6）、极低P值（<0.0001）、调整后的R平方（0.985）和预测的R平方（0.947）。此外，失拟不显著，这意味着模型是显著的。

结果

该模型通过三维表面图追踪设计中添加剂的最优值。在最优条件下，Bi₂O₃和TiO₂的摩尔比在表面积约为1.25处获得，使非线性系数在约20处最大化。此外，该模型预测了理想条件下添加剂的最优用量。在这种情况下，条件包括最小标准误差（0.35）和最大非线性度（20.03），而Bi₂O₃（1.24 mol%）和TiO₂（1.27 mol%）的摩尔比在范围内。作为解决方案的该条件通过进一步实验进行测试以确认。实验结果表明，获得的非线性度值21.6与预测模型非常接近。