Ngo, Nguyen HoaiNguyen, Anh QuangBufler, Fabian M.Kamakura, YoshinariMutoh, HidekiShimura, TakayoshiHosoi, TakujiWatanabe, HeijiMatagne, PhilippeShimonomura, KazuhiroTakehara, KohseiCharbon, EdoardoEtoh, Takeharu Goji2021-01-122021-01-122021-01-122020-12-0210.3390/s20236895https://infoscience.epfl.ch/handle/20.500.14299/174635The theoretical temporal resolution limit tT of a silicon photodiode (Si PD) is 11.1 ps. We call “super temporal resolution” the temporal resolution that is shorter than that limit. To achieve this resolution, Germanium is selected as a candidate material for the photodiode (Ge PD) for visible light since the absorption coefficient of Ge for the wavelength is several tens of times higher than that of Si, allowing a very thin PD. On the other hand, the saturation drift velocity of electrons in Ge is about 2/3 of that in Si. The ratio suggests an ultra-short propagation time of electrons in the Ge PD. However, the diffusion coefficient of electrons in Ge is four times higher than that of Si. Therefore, Monte Carlo simulations were applied to analyze the temporal resolution of the Ge PD. The estimated theoretical temporal resolution limit is 0.26 ps, while the practical limit is 1.41 ps. To achieve a super temporal resolution better than 11.1 ps, the driver circuit must operate at least 100 GHz. It is thus proposed to develop, at first, a short-wavelength infrared (SWIR) ultra-high-speed image sensor with a thicker and wider Ge PD, and then gradually decrease the size along with the progress of the driver circuits.ultra-high-speedsuper temporal resolutiontemporal resolution limitimage sensorvisible lightSWIRgermaniumtext::journal::journal article::research article