非对称量子阱结构中的隧穿特性

5th International Workshop on Laser and Fiber-Optical Networks Modeling, 2003. Proceedings of LFNM 2003. Pub Date : 2003-11-17 DOI:10.1109/LFNM.2003.1246138

A. Shulika, V. Lysak, I. Sukhoivanov

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引用次数: 0

摘要

不对称量子阱结构(AMQW)是具有不同深度、宽度和形状的量子阱的层状半导体异质结构。根据原因，有尺寸、组成和复合AMQW，这定义了潜在的轮廓。在具有多量子阱和AMQW的SOA中，以及在量子阱激光器中，载流子输运效应变得非常重要，并且控制着沿有源区域的非均匀载流子分布。在多量子阱动力学模拟中，隧道传输通常被忽略。然而，在室温和薄屏障条件下，隧道作用可以显著地促进其他输运过程。隧穿是载流子在阱之间的转移，而它们的能量没有变化。由于所考虑的结构是多层量子阱，这种载流子转移提供了共振行为。为了在速率方程的框架中考虑隧道效应，我们用隧道时间来描述隧道速率。对于隧穿时间的计算，我们采用半经典处理框架下的群速度概念。我们的模拟表明，隧道挖掘时间可以与其他运输时间相当，甚至更短。

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Tunneling peculiarities in asymmetrical quantum-well structures

Asymmetrical quantum-well structures (AMQW) are layered semiconductor heterostructures having quantum wells of various depth, width, and shape. There are dimensional, compositional, and compound AMQW depending on the cause, which defines potential profile. In SOA with multiple quantum-wells and AMQW as well as in quantum-well lasers carrier transport effects become important and govern nonuniform carrier distribution along the active area. As a rule tunneling transfer is neglected under simulation of multiple quantum-well dynamics. However, tunneling can make significant concurrence for other transport processes under room temperature and thin barriers. The tunneling is the transfer of charge carriers between wells without variation of their energy. Since the structure under consideration is multilayered quantum wells this kind of carrier transfer provides resonant behavior. To take tunneling into account in the frame of rate equations we describe the tunneling rate by means tunneling time. For tunneling time computation we use the group velocity conception in the frame of semiclassical treatment. Our simulations have showed that tunneling time can be comparable to other transport times and even less.

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5th International Workshop on Laser and Fiber-Optical Networks Modeling, 2003. Proceedings of LFNM 2003.

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