Cationic substitution, dynamical stability, thermal stability, electronic and thermoelectric properties in 2D dialkali metal monoxides via DFT and ML approach.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-07-28 DOI:10.1038/s41598-025-11352-9

S Chellaiya, Thomas Rueshwin, R D Eithiraj

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引用次数: 0

Abstract

Using the WIEN2k software, Density Functional Theory (DFT) was applied to analyse the impact of cationic substitution on the physical features of the 1T-K₂O monolayer. Phonon dispersion analysis confirmed dynamical stability, Ab-initio Molecular Dynamics (AIMD) simulations validated thermal stability, and cohesive energy calculations ensured thermodynamic stability of 1T-K₂O. Based on the phonon studies, both 1T-KNaO and 1T-KRbO are dynamically unstable with a slightly visible imaginary frequency. Specifically, for electronic property assessment, generalized gradient approximation (GGA) and hybrid exchange-correlation functionals were utilized. This study unveiled the 1T-KXO (X = Na, K, Rb) monolayers as an indirect band gap semiconductor, for 1T-K₂O, 1T-KNaO and 1T-KRbO were 0.94 eV (1.84 eV), 1.03 eV (1.94 eV) and 0.84 eV (1.77 eV) obtained implementing GGA and hybrid functionals, respectively. Using a machine learning (ML) approach, the band gap was predicted as 1.45 eV (0.85 eV) for 1T-K₂O, 1.79 eV (0.97 eV) for 1T-KNaO, and 1.17 eV (0.72 eV) for 1T-KRbO, with random forest regression (linear regression) method. The physical properties were tailored by the impact of cationic substitution on the 1T-K₂O were studied. The variation in the physical properties were investigated. Optical analysis indicated a strong absorption coefficient, underscoring the 1T-KXO monolayers potential for photovoltaic applications in the UV region. The ZT value obtained at room temperature are 0.58, 0.86 and 0.69 for 1T-K₂O, 1T-KNaO and 1TKRbO, respectively. Additionally, the 1T-KNaO demonstrated promising thermoelectric properties, at 400 K achieving a figure of merit (ZT) of 0.93, indicating its suitability for waste heat recovery. A ML model was trained to predict the ZT of 1T-KXO using random forest regression and linear regression.

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二维双碱金属氧化物的阳离子取代、动力学稳定性、热稳定性、电子和热电性质。

利用WIEN2k软件，应用密度泛函理论（DFT）分析了阳离子取代对1T-K2O单层物理特性的影响。声子色散分析证实了1T-K2O的动力学稳定性，Ab-initio分子动力学（AIMD）模拟验证了热稳定性，内聚能计算确保了1T-K2O的热力学稳定性。基于声子研究，1T-KNaO和1T-KRbO都是动态不稳定的，虚频率略可见。具体而言，在电子属性评估中，使用了广义梯度近似（GGA）和混合交换相关函数。本研究揭示了1T-KXO （X = Na， K, Rb）单分子层作为间接带隙半导体，1T-K2O、1t - kao和1T-KRbO分别为0.94 eV （1.84 eV）、1.03 eV （1.94 eV）和0.84 eV （1.77 eV）实现GGA和杂化官能团。采用随机森林回归（线性回归）方法，预测了1T-K2O的带隙为1.45 eV (0.85 eV)， 1t - kao的带隙为1.79 eV (0.97 eV)， 1T-KRbO的带隙为1.17 eV （0.72 eV）。研究了阳离子取代对1T-K2O的影响。研究了其物理性质的变化。光学分析表明，1T-KXO单层膜具有很强的吸收系数，具有在紫外区光伏应用的潜力。1T-K2O、1t - kao和1TKRbO的室温ZT值分别为0.58、0.86和0.69。此外，1T-KNaO表现出了良好的热电性能，在400 K时达到了0.93的优值（ZT），表明其适合余热回收。使用随机森林回归和线性回归训练ML模型来预测1T-KXO的ZT。

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

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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