Voltage Transfer Characteristic Matching by Different Nanosheet Layer Numbers of Vertically Stacked Junctionless CMOS Inverter for SoP/3D-ICs applications
P. Sung, C. Chang, L. Chen, K. Kao, C. Su, Tzu-Han Liao, C.-C. Fang, C. Wang, T. Hong, Che-Yu Jao, Hui-Shun Hsu, S. Luo, Y.-S. Wang, H.-F. Huang, J. Li, Y. Huang, F. Hsueh, C. Wu, Y.-M. Huang, F. Hou, G. Luo, Y. Huang, Y.-L. Shen, W. C. Ma, K. Huang, K. Lin, S. Samukawa, Y. Li, G. Huang, Y. Lee, J.-Y. Li, W. Wu, J. Shieh, T. Chao, W. Yeh, Y. Wang
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引用次数: 11
Abstract
For the first time, CMOS inverters with different numbers of vertically stacked junctionless (JL) nanosheets (NSs) are demonstrated. All fabrication steps were below 600 °C, and 8-nm thick poly-Si NSs with smooth surface roughness were formed by a dry etching process. Compared to single channel devices, stacked n/p-channel FETs exhibit higher on-current with low leakage current. Furthermore, a common-gate process was performed for the fabrication of CMOS inverters. By adjusting the NS layer numbers for n/pFETs, respectively, the voltage transfer characteristics (VTCs) of the CMOS inverter can be matched much better to reduce the noise margin due to on-current matching without area penalty. This work experimentally demonstrates a new configuration of CMOS inverters on stacked NSs, which is promising for System-on-Panel (SoP) and 3D-ICs applications.
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