2D Simulation Study of p-type TFTs with Chemically Deposited Poly-PbS Active Channel
Abstract
In this work, the two-dimensional (2D) numerical simulation of p-type poly-PbS
TFT electrical characteristics are performed using a physically based device
simulator Atlas/Silvaco. The analytical expressions of defect density models
for acceptor- and donor-like traps are dened for poly-PbS thin lm material
deposited with chemical bath deposition technique. The parameters of defect
density model are optimized based on Levenberg-Marquardt algorithm to t
simulated and experimental results of TFTs. It is shown that the spatially uniform
density of defect states method used for trapped charge evaluation in Atlas
gives good agreement between simulated and experimental characteristics. An
important presence of deep (Gaussian) acceptor- and donor-like density of states
in poly-PbS band gap is conrmed. By controlling cation (donor-like) and anion
(acceptor-like) vacancies of poly-PbS lms could improved the performance of
p-type TFTs.
Keywords
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