p-i-n二极管纵向光学声子-等离子体耦合太赫兹辐射的研究

Q3 Engineering

Nanoscience and Nanotechnology - Asia Pub Date : 2020-11-30 DOI:10.2174/1876402911666190820101307

N. P. The

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引用次数: 0

摘要

室温下红外域太赫兹辐射在科学技术中有着广泛的应用，特别是在图像分析和处理技术中。本文介绍了一种相对简单的方法来研究p-i-n二极体结构中纵向光学声子和相干等离激元耦合产生的太赫兹辐射。通过对二极管绝缘区两个相邻点之间的电压进行快速傅立叶变换(FFT)，得到了该二极管的频谱。对光激发载流子密度为17 1.0×10 cm-3 ~ 18 3.0×10 cm-3、绝缘层尺寸为500 nm的GaAs半导体器件进行了数值计算。为了研究p-i-n二极管中LO声子的耦合，在空间分辨率为1A°，时间分辨率为0.20 fs的条件下，在模拟载流子动力学的同时求解了密度振动方程。我们通过求解泊松方程，推导出在考虑和不考虑耦合的情况下沿x轴的势。由绝缘层中相距10 nm的两层电压的FFT得到的频谱(i)。由两个相邻点之间的电压的傅里叶变换得到的频谱显示了有和没有LO声子-等离子体耦合。我们可以很容易地观察到与本体半导体的频率值接近的模式的存在。值得注意的是，我们的计算结果与ibanez等人在《物理学》杂志上测量的实验结果基本一致。中国生物医学工程学报，2009(5):391 - 391。本文提出了一种相对简单的方法，利用绝缘半导体区相邻两点电压的FFT来研究LO声子-等离子体激元在p-i-n二极管结构中耦合产生的太赫兹辐射。电压由与电荷密度有关的电位通过泊松方程计算得到。对载流子密度为17 1.0×10 cm-3 ~ 18 3.0×10 cm-3的GaAs半导体器件进行了数值计算。我们的模拟计算表明，在适当的光激发载流子密度下，会出现两种强耦合的LO声子-等离子体相干模式。

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Investigation of THz Radiation from Longitudinal Optical Phonon- Plasmon Coupling in p-i-n Diodes

Terahertz radiation (THz) in infrared domain at room temperature has many applications in science and technology, especially in the technology of analyzing and processing image. This paper introduces a relatively simple method to investigate the Terahertz radiation from the coupling of Longitudinal Optical (LO) phonon and coherent plasmon in p-i-n diode structure. The frequency spectra are found from the Fast Fourier Transform (FFT) of the voltage between two neighboring points in the insulating region of this diode. Numerical calculations have been applied for GaAs semiconductor device with the photo-excited carrier density ranging from 17 1.0×10 cm-3 to 18 3.0×10 cm-3 and the insulating layer size of 500 nm. In order to study of the coupling of LO phonon in p-i-n diode based on the EMC simulations, the equation of density vibration is solved simultaneously with the simulation of carrier dynamics, this is performed with spatial resolution of 1A° and time resolution of 0.20 fs . We solve the Poisson’s equation to derive the potentials along the x-axis in both cases with and without taking into account the coupling. The frequency spectrum derived from the FFT of the voltage of two layers separated by a distance 10 nm in insulating layer (i). The frequency spectrum derived from the Fourier transform of the voltage between two neighboring points with and without LO phonon–plasmon coupling is shown. We can easily observe the existence of the modes which are close to the frequency values of bulk semiconductor. It should be noted that, our calculations are reasonable agreement with experiments measured by the Ibanez et al in Phys. Rev. B 69 (7), 075314 (2004). In this paper, we present a relatively simple approach to investigate the THz radiation from the coupling of LO phonon-plasmon in p-i-n diode structure by taking the FFT of the voltage of two neighboring points in insulating semiconductor region. The voltage is calculated through the electric potentials which relate to the charge density via Poisson’s equation. Numerical calculations have been performed for GaAs semiconductor device with carrier density ranging from 17 1.0×10 cm-3 to 18 3.0×10 cm-3. Our simulations calculations show that with appropriate photoexcited carrier density, two strong coupling LO phonon-plasmon coherent modes are appear.

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来源期刊

Nanoscience and Nanotechnology - Asia Engineering-Engineering (all)

CiteScore

1.90

自引率

0.00%

发文量

期刊介绍： Nanoscience & Nanotechnology-Asia publishes expert reviews, original research articles, letters and guest edited issues on all the most recent advances in nanoscience and nanotechnology with an emphasis on research in Asia and Japan. All aspects of the field are represented including chemistry, physics, materials science, biology and engineering mainly covering the following; synthesis, characterization, assembly, theory, and simulation of nanostructures (nanomaterials and assemblies, nanodevices, nano-bubbles, nano-droplets, nanofluidics, and self-assembled structures), nanofabrication, nanobiotechnology, nanomedicine and methods and tools for nanoscience and nanotechnology.