Quantum-to-classical modeling of monolayer Ge2Se2 and its application in photovoltaic devices.

IF 2.6 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Beilstein Journal of Nanotechnology Pub Date : 2024-09-11 eCollection Date: 2024-01-01 DOI:10.3762/bjnano.15.94
Anup Shrivastava, Shivani Saini, Dolly Kumari, Sanjai Singh, Jost Adam
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Abstract

Since the discovery of graphene in 2004, the unique properties of two-dimensional materials have sparked intense research interest regarding their use as alternative materials in various photonic applications. Transition metal dichalcogenide monolayers have been proposed as transport layers in photovoltaic cells, but the promising characteristics of group IV-VI dichalcogenides are yet to be thoroughly investigated. This manuscript reports on monolayer Ge2Se2 (a group IV-VI dichalcogenide), its optoelectronic behavior, and its potential application in photovoltaics. When employed as a hole transport layer, the material fosters an astonishing device performance. We use ab initio modeling for the material prediction, while classical drift-diffusion drives the device simulations. Hybrid functionals calculate electronic and optical properties to maintain high accuracy. The structural stability has been verified using phonon spectra. The E-k dispersion reveals the investigated material's key electronic properties. The calculations reveal a direct bandgap of 1.12 eV for monolayer Ge2Se2. We further extract critical optical parameters using the Kubo-Greenwood formalism and Kramers-Kronig relations. A significantly large absorption coefficient and a high dielectric constant inspired the design of a monolayer Ge2Se2-based solar cell, exhibiting a high open circuit voltage of V oc = 1.11 V, a fill factor of 87.66%, and more than 28% power conversion efficiency at room temperature. Our findings advocate monolayer Ge2Se2 for various optoelectronic devices, including next-generation solar cells. The hybrid quantum-to-macroscopic methodology presented here applies to broader classes of 2D and 3D materials and structures, showing a path to the computational design of future photovoltaic materials.

单层 Ge2Se2 的量子到经典模型及其在光伏设备中的应用。
自 2004 年发现石墨烯以来,二维材料的独特特性引发了人们对其在各种光子应用中用作替代材料的浓厚研究兴趣。过渡金属二掺杂化合物单层已被提议用作光伏电池的传输层,但 IV-VI 族二掺杂化合物的良好特性仍有待深入研究。本手稿报告了单层 Ge2Se2(一种 IV-VI 族二卤化物)、其光电行为及其在光伏领域的潜在应用。当作为空穴传输层使用时,这种材料能产生惊人的器件性能。我们使用 ab initio 建模进行材料预测,同时使用经典漂移扩散驱动器件模拟。混合函数计算电子和光学特性,以保持高精度。声子光谱验证了结构的稳定性。E-k 色散揭示了所研究材料的关键电子特性。计算显示单层 Ge2Se2 的直接带隙为 1.12 eV。我们利用 Kubo-Greenwood 公式和 Kramers-Kronig 关系进一步提取了临界光学参数。明显较大的吸收系数和较高的介电常数激发了单层 Ge2Se2 太阳能电池的设计灵感,该电池在室温下具有 V oc = 1.11 V 的高开路电压、87.66% 的填充因子和超过 28% 的功率转换效率。我们的研究结果主张将单层 Ge2Se2 用于各种光电设备,包括下一代太阳能电池。本文介绍的量子到微观混合方法适用于更广泛的二维和三维材料与结构,为未来光伏材料的计算设计指明了道路。
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
Beilstein Journal of Nanotechnology
Beilstein Journal of Nanotechnology NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
5.70
自引率
3.20%
发文量
109
审稿时长
2 months
期刊介绍: The Beilstein Journal of Nanotechnology is an international, peer-reviewed, Open Access journal. It provides a unique platform for rapid publication without any charges (free for author and reader) – Platinum Open Access. The content is freely accessible 365 days a year to any user worldwide. Articles are available online immediately upon publication and are publicly archived in all major repositories. In addition, it provides a platform for publishing thematic issues (theme-based collections of articles) on topical issues in nanoscience and nanotechnology. The journal is published and completely funded by the Beilstein-Institut, a non-profit foundation located in Frankfurt am Main, Germany. The editor-in-chief is Professor Thomas Schimmel – Karlsruhe Institute of Technology. He is supported by more than 20 associate editors who are responsible for a particular subject area within the scope of the journal.
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