Vapour-liquid-solid growth of ZnO-ZnMgO core-shell nanowires by gold-catalysed molecular beam epitaxy

Kennedy O. W.; White R.; Shaffer M. S. P.; Warburton P. A.

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Vapour-liquid-solid growth of ZnO-ZnMgO core-shell nanowires by gold-catalysed molecular beam epitaxy

机译：金催化分子束外延ZnO-ZnMgo核心壳纳米线的蒸汽 - 液体固体生长

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Nanowire heterostructures, combining multiple phases within a single nanowire, modify functional properties and offer a platform for novel device development. Here, ZnO/ZnMgO core-shell nanowires are grown by molecular beam epitaxy. At growth temperatures above 750 degrees C, Mg diffuses into ZnO making heterostructure growth impossible; at lower shell-growth temperatures (500 degrees C), the core-shell structure is retained. Even very thin ZnMgO shells show increased intensity photoluminescence (PL) across the ZnO band-gap and a suppression in defect-related PL intensity, relative to plain ZnO nanowires. EDX measurements on shell thickness show a correlation between shell thickness and core diameter which is explained by a simple growth model.

机译：纳米线异质结构，将多个相结合在单个纳米线内，修饰功能性质，并为新颖的设备开发提供平台。这里，通过分子束外延生长ZnO / ZnMGO核心壳纳米线。在750℃高于750℃的生长温度下，Mg扩散成ZnO，使异质结构生长不可能; 在较低的壳生长温度（500℃）下，保留核心壳结构。甚至非常薄的ZnMGO壳在ZnO带间隙上显示出增加的强度光致发光（PL），以及相对于普通ZnO纳米线的缺陷相关P1强度抑制。壳体厚度的EDX测量显示壳体厚度和芯直径之间的相关性，其由简单的生长模型解释。

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来源
《Nanotechnology》 |2019年第19期|共5页
作者
Kennedy O. W.; White R.; Shaffer M. S. P.; Warburton P. A.;
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作者单位

UCL London Ctr Nanotechnol 17-19 Gordon St London WC1H 0AH England;

Imperial Coll London Dept Chem Imperial Coll Rd London SW7 2AZ England;

Imperial Coll London Dept Chem Imperial Coll Rd London SW7 2AZ England;

UCL London Ctr Nanotechnol 17-19 Gordon St London WC1H 0AH England;

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正文语种 eng
中图分类特种结构材料;
关键词
nanowires; ZnO; heterostructure; MBE;

机译：纳米线;ZnO;异质结构;MBE;

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专利

1. Vapour-liquid-solid growth of ZnO-ZnMgO core-shell nanowires by gold-catalysed molecular beam epitaxy [J] . Kennedy O. W., White R., Shaffer M. S. P., Nanotechnology . 2019,第19期

机译：金催化分子束外延ZnO-ZnMgo核心壳纳米线的蒸汽 - 液体固体生长
2. Self-catalyzed growth of dilute nitride GaAs/GaAsSbN/GaAs core-shell nanowires by molecular beam epitaxy [J] . Pavan Kumar Kasanaboina, Estiak Ahmad, Jia Li, Applied Physics Letters . 2015,第10期

机译：分子束外延自生生长稀氮化物GaAs / GaAsSbN / GaAs核壳纳米线
3. Molecular beam epitaxy growth of GaAs/InAs core-shell nanowires and fabrication of InAs nanotubes [J] . Rieger T., Luysberg M., Sch?pers T., Nano letters . 2012,第11期

机译：GaAs / InAs核壳纳米线的分子束外延生长及InAs纳米管的制备
4. Impact of Processing and Growth Conditions on the Site-Catalyzed Patterned Growth of GaAs Nanowires by Molecular Beam Epitaxy [C] . Manish Sharma, Pavan Kasanaboina, Shanthi Iyer Nanoengineering: Fabrication, properties, optics, and devices XIV . 2017

机译：加工和生长条件对分子束外延对GaAs纳米线定点催化图案生长的影响
5. Bandgap Tuning of GaAs/GaAsSb(N) Core-Shell Nanowires Grown by Molecular Beam Epitaxy [D] . Kasanaboina, Pavan Kumar. 2016

机译：通过分子束外延生长的GaAs / Gaassb（N）核心壳纳米线的带隙调谐
6. Surface effects of vapour-liquid-solid driven Bi surface droplets formed during molecular-beam-epitaxy of GaAsBi [O] . J. A. Steele, R. A. Lewis, J. Horvat, -1

机译：GaAsBi分子束外延过程中形成的气液固驱动Bi表面液滴的表面效应
7. All-wurtzite (In,Ga)As-(Ga,Mn)As core-shell nanowires grown by molecular beam epitaxy [O] . Siusys, Aloyzas, Sadowski, Janusz, Sawicki, Maciej, 2014

机译：全纤锌矿（In，Ga）as-（Ga，mn）as分子生长的核壳纳米线束外延
8. Bandgap Tuning of GaAs/GaAsSb Core-Shell Nanowires Grown by Molecular Beam Epitaxy. [R] . Kasanaboina, P. K., Ojha, S. K., Sami, S. U., 2015

机译：用分子束外延生长Gaas / Gaassb核壳纳米线的带隙调谐。

Vapour-liquid-solid growth of ZnO-ZnMgO core-shell nanowires by gold-catalysed molecular beam epitaxy

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