As photolithography-based top-down methods are approaching their fundamental limits, new conceptual methods are emerging as possible alternatives to replace them. Alternatives based on bottom-up approach rely on the assembly of basic building blocks such as nanowires. One-dimensional Group IV semiconductors (Ge, SiGe) are very important electronic materials. However, they cannot be used in optoelectronics due to their intrinsic indirect band gap properties. One of the most effective approaches to make them luminescent is the introduction of impurities such as Er3+ ions. Er 3+ is of technologically important because its emission lies at the transmission window of silica. Another focus of our research is to fabricate one-dimensional Er-doped Group IV oxide amplifiers. Ideally, these NWs could be used as building blocks in the field of near-IR nanophotonics.; The basic building block Ge NWs were first fabricated via a vapor-liquid-solid synthetic route. Next, these Ge NWs were doped with Er3+ ions. These NWs were characterized using electron microscopy and spectroscopy, showing that these nanowires possess a core-shell structure. Activation and possible underlying mechanism for the Er-related emission have also been explored.; Since Ge NWs are readily oxidized, Si was introduced to form stable SiGe alloys in order to circumvent this problem. Three different alloyed architectures were prepared. A combination of electron microscopes in concert with both elemental and Raman microanalyses were used to investigate the composition and structure of these Er-doped SiGe NWs. The Er coordination environment and Er-related luminescence properties have also been investigated.; Er-doped group IV oxide nanofibers were fabricated via an electrospinning approach. These nanofibers were then characterized using X-ray diffraction, electron microscopy, and spectroscopy to investigate their structures and compositions. The Er3+ ions in Er-doped GeO2 nanofibers were found to be excited through a GeOx-mediated process.; Lastly, the Er sensitizer, GeOx was introduced deliberately into Er-doped SnO2 nanofibers. These composite nanofiber structures were characterized using electron microscopy and spectroscopy, showing that SnO2 can be reduced by Ge to form Sn metal. A longer Ge deposition time leads to the formation of Ge nanorods. The Er-related luminescence from these sensitized nanofibers has been enhanced by almost 2 orders of magnitude.
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机译:随着基于光刻的自上而下的方法接近其基本极限,新的概念方法正在出现,可能替代它们。基于自下而上方法的替代方法依赖于基本构建模块(例如纳米线)的组装。一维IV族半导体(Ge,SiGe)是非常重要的电子材料。但是,由于它们固有的间接带隙特性,它们不能用于光电。使它们发光的最有效方法之一是引入杂质,例如Er3 +离子。 Er 3+具有重要的技术意义,因为它的发射位于二氧化硅的透射窗口内。我们研究的另一个重点是制造一维掺Er的IV类氧化物放大器。理想情况下,这些近场激光器可以用作近红外纳米光子学领域的基础。基本的Ge Ge NWs首先是通过汽-液-固合成路线制造的。接下来,这些Ge NWs掺有Er3 +离子。使用电子显微镜和光谱法对这些NW进行表征,表明这些纳米线具有核-壳结构。还研究了与Er有关的发射的激活及其可能的潜在机制。由于Ge NWs容易被氧化,因此引入Si来形成稳定的SiGe合金以规避此问题。准备了三种不同的合金结构。将电子显微镜与元素显微分析和拉曼显微分析相结合,用于研究这些掺Er的SiGe NW的组成和结构。还研究了Er配位环境和与Er有关的发光特性。通过电纺丝方法制备了掺的Ⅳ族氧化物纳米纤维。然后使用X射线衍射,电子显微镜和光谱对这些纳米纤维进行表征,以研究其结构和组成。发现掺Er的GeO2纳米纤维中的Er3 +离子通过GeOx介导的过程被激发。最后,将Er敏化剂GeOx故意引入掺Er的SnO2纳米纤维中。这些复合纳米纤维结构通过电子显微镜和光谱学表征,表明SnO2可以被Ge还原形成Sn金属。较长的锗沉积时间导致锗纳米棒的形成。这些敏化纳米纤维的Er相关发光增强了将近2个数量级。
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