Reversely-Synchronized-Stress-Induced Degradation in Polycrystalline Silicon Thin-Film Transistors and Its Suppression by a Bridged-Grain Structure

Abstract

In this letter, a reversely synchronized stress (RSS) is proposed to simulate the working condition of switching thin-film transistors (TFTs) in active-matrix displays. The reliability of polycrystalline silicon (poly-Si) TFTs under RSS is characterized and investigated. RSS brings huge device degradation. A dynamic hot carrier (HC) effect, dependent on transition edges of RSS, dominates the degradation. Combined with a transient simulation, the degradation mechanism under RSS in poly-Si TFTs is discussed and developed. To suppress RSS-induced HC degradation, a bridged-grain (BG) structure is employed in the active layer of poly-Si TFTs. Via BG lines’ reducing the lateral electric field in the channel at source/drain sides, the reliability of BG TFTs under RSS is significantly improved.