For the first time, an in-depth analysis of the intertier dynamic coupling and RF crosstalk of digital circuits in 3D sequential integration enables to conclude on the need of a Ground Plane (GP) for various applications. Experiments in conjunction with TCAD simulations reveal the parasitic capacitances responsible for the dynamic coupling effects and their impact is investigated for a 3D sequential 2-bitcell SRAM cell circuit configuration. Furthermore, we show a greater than 20dB suppression up to 100GHz of the inter-tier RF crosstalk, achieved by the addition of a strategically designed polysilicon Ground Plane between active device layers enabling the possibility of heterogeneous 3DSI integration without metallic Ground Plane. We propose a technological solution to create experimentally a 34nm-thick polysilicon GP of 1.8x10 20 at/cm 3 n-doping and 295Ω/sq sheet resistance.
In this paper, we present a thorough analysis of parasitic coupling effects between different electrodes for a 3D Sequential Integration circuit example comprising stacked devices. More specifically, this study is performed for a Back-Side Illuminated, 4T–APS, 3D Sequential Integration pixel with both its photodiode and Transfer Gate at the bottom tier and the other parts of the circuit on the top tier. The effects of voltage bias and 3D inter-tier contacts are studied by using TCAD simulations. Coupling-induced electrical parameter variations are compared against variations due to temperature change, revealing that these two effects can cause similar levels of readout error for the top-tier readout circuit. On the bright side, we also demonstrate that in the case of a rolling shutter pixel readout, the coupling effect becomes nearly negligible. Therefore, we estimate that the presence of an inter-tier ground plane, normally used for electrical isolation, is not strictly mandatory for Monolithic 3D pixels.
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