具有局部金属后门的石墨烯变容管中量子电容的介电厚度依赖性

M. Ebrish, S. Koester
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引用次数: 3

摘要

两种HfO2靶厚度分别为20 nm(样品A)和10 nm(样品B)的样品的温度依赖性C-V特性如图2和图3所示。结果表明,随着HfO2厚度的减小,电容调谐范围增大。两种样品在室温下的归一化C-V曲线对比如图4所示。从Vg - VDirac = 0到+1.5 V的电容调谐范围,样品A为1.17:1,样品b为1.38:1。图5显示了在相同样品上制造的变容管与MIM电容器的C-V特性的比较。观察到一个非常一致的趋势,即MIM电容器的单位面积电容明显高于变容管。从样品A和样品B中提取的EOT值分别为4.1 nm和2.7 nm。为了更详细地了解这种行为,对温度相关的C-V特性进行了数值模拟,其中石墨烯中的随机电位波动σ用作可调拟合参数[5]。结果如图6所示。拟合的EOT值不能完全解释图5中的电容减小,这一事实有力地表明,变容管的有效器件面积小于布局面积。然而,需要额外的建模,特别是考虑界面陷阱的影响,以及石墨烯和HfO2之间的其他缺陷[6-7],才能充分理解所观察到的行为。在未来,需要进一步研究EOT的缩放,以及在绝缘衬底上制造最终用于谐振器电路的器件。作为初步演示(图7),我们在石英衬底上制作了一个单指变容管,EOT(由MIM电容器确定)为1.9 nm,室温下调谐范围> 1.5:1。
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Dielectric thickness dependence of quantum capacitance in graphene varactors with local metal back gates
The temperature-dependent C-V characteristics for two samples with target HfO2 thicknesses of 20 nm (sample A), and 10 nm (sample B) are shown in Figs. 2 and 3. The results show that the capacitance tuning range increases with decreasing HfO2 thicknesses, as expected. A comparison of the normalized C-V curves for both samples at room temperature is shown in Fig. 4. The capacitance tuning range from Vg - VDirac = 0 to +1.5 V is 1.17:1 for sample A and 1.38:1 for sample B. Fig. 5 shows a comparison of the C-V characteristics for the varactors with MIM capacitors fabricated on the same sample. A very consistent trend is observed where the capacitance-per-unit-area for the MIM capacitors is significantly higher than for the varactors. The EOT values extracted from the MIM capacitors are found to be 4.1 nm and 2.7 nm for samples A and B, respectively. In order to understand this behavior in more detail, numerical modeling was performed on the temperature-dependent C-V characteristics where the random potential fluctuations, σ, in the graphene was used as an adjustable fitting parameter [5]. The results are shown in Fig. 6. The fact that the fitted EOT values cannot completely account for the capacitance reduction in Fig. 5 is a strong indicator that the effective device area of the varactors is less than the layout area. However, additional modeling, particularly taking into account the effect of interface traps, and other imperfections between the graphene and HfO2 [6-7] is needed to fully understand the observed behavior. In the future, further scaling of the EOT needs to be investigated, as well as fabrication of the devices on insulating substrates for eventual use in resonator circuits. As a preliminary demonstration (Fig. 7), we have fabricated a single-finger varactor on a quartz substrate, with EOT (as determined by MIM capacitors) of 1.9 nm and tuning range >;1.5:1 at room temperature.
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