Fractional multiple trapping model of time-of-flight transient photocurrents in amorphous semiconductors

IF 1 4区 物理与天体物理 Q3 PHYSICS, MATHEMATICAL
Y. Goutal, F. Serdouk, A. Boumali, M. L. Benkhedir
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Abstract

The use of the multiple-trapping (MT) model to comprehend the transport of nonequilibrium charge carriers in amorphous semiconductors has proven highly effective. Under specific conditions, this model generates anomalous diffusion equations characterized by fractional time derivatives. This underscores the utility of the MT model in interpreting fractional transport equations, establishing initial and boundary conditions, and developing numerical methods for solving fractional kinetic equations. Also, this work provides a concise overview of applying fractional MT equations to address challenges in time-of-flight (TOF) experiments. Furthermore, it delves into the connection between the MT model and generalized fractional kinetic equations. In addition, the study introduces analytic approximate solutions of the fractional diffusion equation, incorporating MT phenomena and employing Laplace transforms. This approach is suitable for analyzing both the pre- and post-regimes of TOF transient current, applicable to amorphous semiconductors that display either nondispersive or dispersive transport characteristics. The effectiveness of this method is illustrated through numerical simulations of TOF transient current using the inverse Laplace transform technique with the Padé approximation. The practicality of the method is confronted with the experimental data obtained from thin films of amorphous selenium (a-Se), and the results of this confrontation are deemed satisfactory. The results of this study offer a new promising perspective for the two following reasons. First, employing fractional calculus to address the MT equations introduces a distinct approach compared to methodologies in the existing literature. This is substantiated by the inclusion of memory effects in fractional calculus, implying that the present solution is influenced by preceding time steps. Second, the numerical results demonstrate good agreement with experimental data. Consequently, the introduction of fractional calculus has the potential to offer fresh insights into the behavior of charge carriers in amorphous semiconductors.

Abstract Image

非晶半导体中飞行时间瞬态光电流的分数多重捕获模型
摘要 事实证明,使用多重捕获(MT)模型来理解非平衡电荷载流子在非晶半导体中的传输非常有效。在特定条件下,该模型会产生以分数时间导数为特征的异常扩散方程。这凸显了 MT 模型在解释分数输运方程、建立初始条件和边界条件以及开发求解分数动力学方程的数值方法方面的实用性。此外,这项研究还简要概述了如何应用分数 MT 方程来应对飞行时间(TOF)实验中的挑战。此外,研究还深入探讨了 MT 模型与广义分数动力学方程之间的联系。此外,研究还介绍了分数扩散方程的解析近似解,其中包含 MT 现象并采用了拉普拉斯变换。这种方法适用于分析 TOF 瞬态电流的前摄动和后摄动,适用于显示非分散或分散传输特性的非晶半导体。通过使用帕代近似的反拉普拉斯变换技术对 TOF 瞬态电流进行数值模拟,说明了该方法的有效性。该方法的实用性与从非晶硒(a-Se)薄膜中获得的实验数据进行了对比,对比结果令人满意。这项研究的结果提供了一个新的前景,原因有二。首先,与现有文献中的方法相比,采用分数微积分处理 MT 方程引入了一种独特的方法。分数微积分中包含的记忆效应证明了这一点,这意味着当前的解法会受到之前时间步骤的影响。其次,数值结果表明与实验数据十分吻合。因此,分数微积分的引入有可能为非晶半导体中电荷载流子的行为提供新的见解。
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来源期刊
Theoretical and Mathematical Physics
Theoretical and Mathematical Physics 物理-物理:数学物理
CiteScore
1.60
自引率
20.00%
发文量
103
审稿时长
4-8 weeks
期刊介绍: Theoretical and Mathematical Physics covers quantum field theory and theory of elementary particles, fundamental problems of nuclear physics, many-body problems and statistical physics, nonrelativistic quantum mechanics, and basic problems of gravitation theory. Articles report on current developments in theoretical physics as well as related mathematical problems. Theoretical and Mathematical Physics is published in collaboration with the Steklov Mathematical Institute of the Russian Academy of Sciences.
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