全无机 TiX3 过渡金属卤化物纳米线的电子和光学特性

IF 2.9 3区物理与天体物理 Q3 NANOSCIENCE & NANOTECHNOLOGY Physica E-low-dimensional Systems & Nanostructures Pub Date : 2024-08-13 DOI:10.1016/j.physe.2024.116071

Junais Habeeb Mokkath

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引用次数: 0

摘要

过渡金属卤化物在光伏和光电子领域的应用前景广阔。本研究利用第一原理密度泛函理论（DFT）和随时间变化的 DFT 计算，系统地研究了全无机 TiX3（X = Cl/Br/I）过渡金属卤化物纳米线的电子和光学特性。研究结果强调了特定卤化物类型对 TiX3 纳米线电子和光学特性的重要影响。特别是，卤化物类型对费米级附近的电子态和红外光吸收特性有重大影响。一个重要发现是在 TiCl3 纳米线中观察到了特殊的光吸收强度，达到了令人印象深刻的 26000 cm-1。这项研究还通过 "过渡贡献图"（Transition Contribution Maps）深入了解了激子的产生。除了理论意义之外，我们还希望从这项研究中获得的启示将有助于利用全无机卤化物包晶石开发有源光学器件。

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Electronic and optical properties of all-inorganic TiX3 transition metal halide nanowires

Transition metal halides are promising for use in photovoltaics and optoelectronics. This research systematically investigated the composition-dependent electronic and optical properties of all-inorganic TiX₃ (X = Cl/Br/I) transition metal halide nanowires using first-principles density functional theory (DFT) and time-dependent DFT calculations. The findings emphasize the significant impact of the specific halide type on the electronic and optical characteristics of TiX₃ nanowires. Particularly, the type of halide significantly influences the electronic states near the Fermi level and the infrared photoabsorption properties. An important discovery is the exceptional photoabsorption strength observed in the TiCl₃ nanowire, reaching an impressive value of 26000 cm⁻¹. The study also offers insights into exciton generation, aided by Transition Contribution Maps. Apart from its theoretical implications, we expect that the insights gained from this research will contribute to the advancement of active optical devices utilizing all-inorganic halide perovskites.

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来源期刊

Physica E-low-dimensional Systems & Nanostructures 物理-纳米科技

CiteScore

7.30

自引率

6.10%

发文量

356

审稿时长

65 days

期刊介绍： Physica E: Low-dimensional systems and nanostructures contains papers and invited review articles on the fundamental and applied aspects of physics in low-dimensional electron systems, in semiconductor heterostructures, oxide interfaces, quantum wells and superlattices, quantum wires and dots, novel quantum states of matter such as topological insulators, and Weyl semimetals. Both theoretical and experimental contributions are invited. Topics suitable for publication in this journal include spin related phenomena, optical and transport properties, many-body effects, integer and fractional quantum Hall effects, quantum spin Hall effect, single electron effects and devices, Majorana fermions, and other novel phenomena. Keywords: • topological insulators/superconductors, majorana fermions, Wyel semimetals; • quantum and neuromorphic computing/quantum information physics and devices based on low dimensional systems; • layered superconductivity, low dimensional systems with superconducting proximity effect; • 2D materials such as transition metal dichalcogenides; • oxide heterostructures including ZnO, SrTiO3 etc; • carbon nanostructures (graphene, carbon nanotubes, diamond NV center, etc.) • quantum wells and superlattices; • quantum Hall effect, quantum spin Hall effect, quantum anomalous Hall effect; • optical- and phonons-related phenomena; • magnetic-semiconductor structures; • charge/spin-, magnon-, skyrmion-, Cooper pair- and majorana fermion- transport and tunneling; • ultra-fast nonlinear optical phenomena; • novel devices and applications (such as high performance sensor, solar cell, etc); • novel growth and fabrication techniques for nanostructures

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