Electrode-stress-induced nanoscale disorder in Si quantum electronic devices

J. Park; Y. Ahn; J. A. Tilka; K. C. Sampson; D. E. Savage; J. R. Prance; C. B. Simmons; M. G. Lagally; S. N. Coppersmith; M. A. Eriksson; M. V. Holt; P. G. Evans

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Electrode-stress-induced nanoscale disorder in Si quantum electronic devices

机译：Si量子电子器件中的电极应力诱导的纳米级无序

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Disorder in the potential-energy landscape presents a major obstacle to the more rapid development of semiconductor quantum device technologies. We report a large-magnitude source of disorder, beyond commonly considered unintentional background doping or fixed charge in oxide layers: nanoscale strain fields induced by residual stresses in nanopatterned metal gates. Quantitative analysis of synchrotron coherent hard x-ray nanobeam diffraction patterns reveals gate-induced curvature and strains up to 0.03% in a buried Si quantum well within a Si/SiGe heterostructure. Electrode stress presents both challenges to the design of devices and opportunities associated with the lateral manipulation of electronic energy levels.

机译：势能格局中的混乱为半导体量子器件技术的较快发展提出了主要障碍。我们报道了大范围的无序来源，超出了通常认为的无意背景掺杂或氧化物层中的固定电荷：由纳米图案化金属门中的残余应力引起的纳米级应变场。对同步加速器相干硬X射线纳米束衍射图进行定量分析，发现在Si / SiGe异质结构内的掩埋Si量子阱中，栅诱导的曲率和应变高达0.03％。电极应力既对设备设计提出了挑战，也带来了与电子能级的横向操纵相关的机会。

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《APL Materials》 |2016年第6期|共页
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J. Park; Y. Ahn; J. A. Tilka; K. C. Sampson; D. E. Savage; J. R. Prance; C. B. Simmons; M. G. Lagally; S. N. Coppersmith; M. A. Eriksson; M. V. Holt; P. G. Evans;
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Electrode-stress-induced nanoscale disorder in Si quantum electronic devices

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