Adaptive learning of prediction and simulation on the influence of Fe thickness on the energy gap of ZnO/Fe/ZnO tri-layer thin films

IF 1.7 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

The European Physical Journal B Pub Date : 2025-07-21 DOI:10.1140/epjb/s10051-025-00995-2

R. A. Mohamed, E. Baradács, H. E. Atyia, P. Pál, M. Y. El-Bakry, G. Katona, S. S. Fouad, Z. Erdélyi

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Abstract

This work focuses on the investigation of the effect of Iron (Fe) interlayer thickness, on the experimental, simulation and prediction of the optical energy gap of ZnO/Fe/ZnO tri-layer thin films. The optical properties and the modeling were studied by varying the Fe interlayer thickness from 20 to 80 nm. The tri-layer thin films were successfully fabricated using atomic layer deposition for the ZnO layers and direct current magnetron sputtering unit for Fe layers. The optical transmission in the range of 400–2500 nm has been studied to determine the variation of absorption coefficient (α) and optical gap \(({E}_{\text{g}})\) of the investigated thin films. The appearance of ZnO/Fe/ZnO system as a Fabry–Pérot “interference filter” is consistent with the optical transmission curves. Adaptive neuro-fuzzy inference system (ANFIS) was utilized for simulation and prediction based on experimental data. Using ANFIS enabled the prediction of the transmittance of different Fe interlayer thicknesses for the unmeasured values. The E_g, showed a noticeable dependence on the Fe layer thickness, where a significant reduction decreasing from 2.45 to 1.75 eV was observed, which has been attributed to the increase of the metallicity, while the metallization criterion on the basis of E_g showed a decreasing trend from 0.35 to 0.312, which suggests potential applications for nonlinear optics. The evaluating mean squared error of the ANFIS model was indicating the positive influence of the used model. Therefore, modeling approach has computational efficiency and flexibility that provides a rapid and reliable technique to investigate the impact of Fe thickness on the energy gap of ZnO/Fe/ZnO tri-layer thin films.

Graphical abstract

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Fe厚度对ZnO/Fe/ZnO三层薄膜能隙影响的自适应学习预测与模拟

本文主要研究了铁（Fe）层间厚度对ZnO/Fe/ZnO三层薄膜光学能隙的实验、模拟和预测的影响。通过改变铁层间厚度在20 ～ 80 nm之间的变化，研究了其光学性质和模型。采用原子层沉积法制备了ZnO薄膜，采用直流磁控溅射装置法制备了Fe薄膜。研究了400 ～ 2500 nm范围内薄膜的光透射特性，测定了薄膜的吸收系数（α）和光隙\(({E}_{\text{g}})\)的变化。ZnO/Fe/ZnO体系作为法布里-帕氏“干涉滤光片”的外观与光学传输曲线一致。利用自适应神经模糊推理系统（ANFIS）对实验数据进行仿真和预测。利用ANFIS可以对未测值进行不同铁层厚度透射率的预测。Eg对Fe层厚度有明显的依赖性，从2.45 eV显著降低到1.75 eV，这归因于金属丰度的增加，而基于Eg的金属化判据则从0.35 eV下降到0.312 eV，这表明了非线性光学的潜在应用前景。评价ANFIS模型的均方误差表明所使用模型的积极影响。因此，该建模方法具有计算效率和灵活性，为研究Fe厚度对ZnO/Fe/ZnO三层薄膜能隙的影响提供了一种快速可靠的技术。图形摘要

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