Transient photoluminescence study on spin dynamics in InGaAs-based coupled nanostructures of quantum dots with quantum wells

2016 IEEE 16th International Conference on Nanotechnology (IEEE-NANO) Pub Date : 2016-08-01 DOI:10.1109/NANO.2016.7751318

Kazuki Takeishi, Shula L. Chen, J. Takayama, Kodai Itabashi, Masayuki Urabe, A. Murayama

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Abstract

We have made transient photoluminescence (PL) study on electron-spin dynamics in InGaAs-based coupled nanostructures of quantum dots (QDs) with quantum wells (QWs). Self-assembled InGaAs QDs were grown integrated with an InGaAs QW through a GaAs tunneling barrier or embedded in a GaAs QW. Time-resolved circularly polarized PL in the QDs was measured as a function of temperature after optical spin excitation selectively in the QW, reflecting electron-spin polarization injected from the QW into QDs. We show the spin injection dynamics induced by spin tunneling and subsequent energy relaxation from the QW into QDs in the former coupled QDs. Spin relaxation at excited states in the QDs after the dynamical spin injection is shown as a function of temperature. These coupled QD samples exhibit thermally persistent spin polarization up to 200 K, originating from ultrafast and thus efficient spin injection as well as longer spin-relaxation times compared to radiative decay times in the QDs after the injection.

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基于ingaas的量子点耦合纳米结构中自旋动力学的瞬态光致发光研究

利用瞬态光致发光(PL)研究了ingaas基量子点(QDs)与量子阱(QWs)耦合纳米结构的电子自旋动力学。自组装InGaAs量子点可以通过GaAs隧道势垒与InGaAs量子阱集成或嵌入GaAs量子阱中。在量子点中选择性地进行光自旋激发后，测量了量子点中时间分辨圆极化PL随温度的变化，反映了从量子点注入到量子点中的电子自旋极化。我们展示了由自旋隧穿引起的自旋注入动力学和随后的能量弛豫从量子点到前耦合量子点的量子点。动态自旋注入后量子点激发态的自旋弛豫是温度的函数。这些耦合的量子点样品表现出高达200k的热持久自旋极化，这源于超快和高效的自旋注入，以及与注入后量子点的辐射衰减时间相比，更长的自旋弛豫时间。

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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2016 IEEE 16th International Conference on Nanotechnology (IEEE-NANO)

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