Atomistic Simulation of Nanoscale Devices

IF 2.3 Q3 NANOSCIENCE & NANOTECHNOLOGY
Youseung Lee, Jiang Cao, M. Luisier
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引用次数: 0

Abstract

Device simulation is nowa­days fully integrated into the production tool chain of transistors. The geometry of the latter can be carefully optimized, possible design pitfalls can be identified early on, and the obtained experimental data can be analyzed in detail thanks to state-of-the-art technology computer aided design tools. However, on the one hand, the dimensions of transistors are reaching the atomic scale. On the other hand, novel functionalities (e.g., light emission/detection) and materials, for example III-V semiconductors, are being added to silicon-based chips. To cope with these challenges it is crucial that device simulators go beyond classical theories, pure electronic transport, and continuum models. The inclusion of quantum mechanical phenomena, electro-thermal effects, and light-matter interactions in systems made of thousands of atoms and of various materials has become critical. In this paper, we review one approach that satisfies all these requirements, the Non-equilibrium Green’s Function (NEGF) formalism, focusing on its combination with ab initio bandstructure models. The NEGF method allows to treat electrical, thermal, and optical transport at the quantum mechanical level in multi-material, multi-functional devices, without any empirical parameters. Besides advanced logic switches, it can be used to simulate e.g., photo-detectors, thermoelectric generators, or memory cells composed of almost any materials, in the ballistic limit of transport and in the presence of scattering. The key features of NEGF are summarized first, then selected applications are presented, finally challenges and opportunities are discussed.
纳米级器件的原子模拟
器件模拟现在已经完全集成到晶体管的生产工具链中。后者的几何形状可以仔细优化,可以尽早识别可能的设计陷阱,并且可以借助最先进的技术计算机辅助设计工具对获得的实验数据进行详细分析。然而,一方面,晶体管的尺寸正在达到原子级。另一方面,新型功能(例如,发光/检测)和材料,例如III-V族半导体,正在被添加到硅基芯片中。为了应对这些挑战,设备模拟器必须超越经典理论、纯电子传输和连续体模型。在由数千个原子和各种材料组成的系统中包含量子力学现象、电热效应和光物质相互作用已变得至关重要。在本文中,我们回顾了一种满足所有这些要求的方法,即非平衡格林函数(NEGF)形式,重点是它与从头算带结构模型的结合。NEGF方法允许在没有任何经验参数的情况下,在多材料、多功能器件中以量子力学水平处理电、热和光传输。除了先进的逻辑开关外,它还可以用于模拟例如光电探测器、热电发生器或几乎由任何材料组成的存储单元,在传输的弹道极限和存在散射的情况下。首先概述了NEGF的主要特点,然后介绍了选定的应用,最后讨论了挑战和机遇。
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来源期刊
IEEE Nanotechnology Magazine
IEEE Nanotechnology Magazine NANOSCIENCE & NANOTECHNOLOGY-
CiteScore
2.90
自引率
6.20%
发文量
46
期刊介绍: IEEE Nanotechnology Magazine publishes peer-reviewed articles that present emerging trends and practices in industrial electronics product research and development, key insights, and tutorial surveys in the field of interest to the member societies of the IEEE Nanotechnology Council. IEEE Nanotechnology Magazine will be limited to the scope of the Nanotechnology Council, which supports the theory, design, and development of nanotechnology and its scientific, engineering, and industrial applications.
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