Electrical resistivity mapping of potassium-doped few-layer CVD graphene by EBAC measurements

Journal of Physics D Pub Date : 2023-11-08 DOI:10.1088/1361-6463/ad0aee

Yuki Okigawa, Hideaki Nakajima, Toshiya Okazaki, Takatoshi Yamada

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Abstract

Abstract The electron beam absorbed current (EBAC) method identifies the open and/or short points in various semiconductor devices, which can be applied to characterize the current path and local resistance in graphene. In this study, potassium (K)-doped few-layer graphene with inhomogeneous K atoms seemed to be one of the appropriate materials to characterize the current path by EBAC. Nonuniform contrast in the EBAC image due to inhomogeneous local resistances is observed, which is explained by the variation of the Fermi level in the graphene channel from the G-band peak shifts from Raman spectroscopy. The changes in the contrast of the EBAC images are obtained by applying a gate voltage. These changes are attributed to the modulation of the local carrier densities by applying the gate voltage. For comparison, uniform contrast in EBAC images and uniform G-band peak positions of undoped few-layer graphene FETs are confirmed. The obtained results suggest that homogeneous Fermi level leads to uniform current path. EBAC enables us to evaluate the uniformity of local resistance and current through a pass in the graphene channel, which can be applied to other two-dimensional materials, such as transition metal dichalcogenides, graphene oxide and h -BN.

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用EBAC测量方法绘制掺钾少层CVD石墨烯的电阻率图

电子束吸收电流(EBAC)方法可以识别各种半导体器件中的开路点和/或短点，可用于表征石墨烯中的电流路径和局部电阻。在这项研究中，钾(K)掺杂的具有不均匀K原子的少层石墨烯似乎是EBAC表征电流路径的合适材料之一。由于局部电阻不均匀，EBAC图像的对比度不均匀，这可以通过拉曼光谱的g波段峰移来解释石墨烯通道中费米能级的变化。通过施加栅极电压获得EBAC图像对比度的变化。这些变化归因于通过施加栅极电压对局部载流子密度的调制。为了进行比较，证实了未掺杂的少层石墨烯fet的EBAC图像对比度均匀，g波段峰位置均匀。所得结果表明，均匀的费米能级导致均匀的电流路径。EBAC使我们能够评估通过石墨烯通道的局部电阻和电流的均匀性，这可以应用于其他二维材料，如过渡金属二硫族化合物、氧化石墨烯和氢氮化硼。

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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Journal of Physics D

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