Effect of Different Sized Multi Walled Carbon Nanotubes on the Barrier Potential and Trap Concentration of Malachite Green Dye Based Organic Device

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
Sudipta Sen, N. Manik
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引用次数: 5

Abstract

Abstract Present work shows effect of 8 nm diameter and 30 nm diameter multi walled carbon nanotubes (MWCNT) on the barrier potential and trap concentration of Malachite Green (MG) dye based organic device. MWCNTs are basically a bundle of concentric single-walled carbon nanotubes with different diameters. In this work, ITO coated glass substrate and aluminium have been used as front electrode and back electrode respectively and the spin coating method is used to prepare the MG dye based organic device. It has been observed that both barrier potential and trap concentration are in correlation. Estimation of both these parameters has been done from current-voltage characteristics of the device to estimate the trap energy and the barrier potential of the device. Device turn-on voltage or the transition voltage is also calculated by using current-voltage characteristics. In presence of 8 nm diameter MWCNT, the transition voltage is reduced from 3.9 V to 2.37 V, the barrier potential is lowered to 0.97 eV from 1.12 eV and the trap energy is lowered to 0.028 eV from 0.046 eV whereas incorporation of 30 nm diameter MWCNT shows reduction of transition voltage from 3.9 V to 2.71 V and a reduction of barrier potential and trap concentration from 1.12 eV to 1.03 eV and from 0.046 eV to 0.035 eV respectively. Presence of both 8 nm diameter and 30 nm diameter MWCNT lowers trap energy approximately to 39% and 24% respectively and lowers barrier potential approximately to 13% and 8% respectively. Estimation of barrier potential is also done by Norde method which shows lowering of the value from 0.88 eV to 0.79 eV and from 0.88 eV to 0.84 eV in presence of both 8 nm and 30 nm diameter multi walled carbon nanotubes respectively. Calculation of barrier potential from both the I-V characteristics and Norde method are in unison with each other. Indication of enhancement of charge flow in the device can be ascribed to the truncated values of barrier potential and trap energy.
不同尺寸的多壁碳纳米管对孔雀石绿染料基有机器件的势垒电位和阱浓度的影响
摘要本文研究了直径为8 nm和30 nm的多壁碳纳米管(MWCNT)对孔雀石绿(MG)染料基有机器件的势垒电位和陷阱浓度的影响。MWCNTs基本上是一束不同直径的同心单壁碳纳米管。本文采用ITO镀膜玻璃基片和铝分别作为前电极和后电极,采用自旋镀膜法制备MG染料基有机器件。已经观察到势垒势和圈闭浓度是相关的。根据器件的电流-电压特性对这两个参数进行了估计,从而估计出器件的阱能和势垒势。器件的导通电压或过渡电压也可以通过使用电流-电压特性来计算。存在8纳米直径MWCNT,转换电压从3.9 V至2.37 V,减少潜在的障碍从1.12降至0.97 eV eV和陷阱能量从0.046降至0.028 eV电动车而整合30 nm直径MWCNT显示减少过渡电压3.9 V至2.71 V和减少潜在障碍和陷阱浓度从1.12 eV到1.03 eV和分别0.046 eV 0.035 eV。8nm直径和30nm直径的MWCNT的存在分别将捕获能降低约39%和24%,将势垒势降低约13%和8%。用Norde方法对势垒电位进行了估计,结果表明,在直径为8 nm和30 nm的多壁碳纳米管存在下,势垒电位分别从0.88 eV降至0.79 eV和从0.88 eV降至0.84 eV。用I-V特性和Norde方法计算势垒势是一致的。器件中电荷流增强的迹象可归因于势垒势和阱能的截断值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Advances in Materials Science
Advances in Materials Science MATERIALS SCIENCE, MULTIDISCIPLINARY-
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