Two different drain field relief architectures, lightly doped drain (LDD) and gate overlapped LDD (GOLDD), for polysilicon TFT have been analyzed and compared to conventional self-aligned (SA) devices. The introduction of LDD regions improves off-current, kink effect and electrical stability if compared to SA devices. However, a parasitic resistance effect is also introduced, thus limiting the benefits of LDD structures. GOLDD architecture overcomes this drawback, but, more importantly, show improved off-current and kink effect and exceptionally high electrical stability. The experimental results have been explained by analyzing the electric field distributions, obtained by two-dimensional numerical simulations, while a new tool to explain hot-carrier induced modifications in polysilicon TFTs was developed.
Comparative analysis of advanced polysilicon thin-film transistor architectures for drain field relief.
Fortunato G;Valletta A;Cuscunà M;Mariucci L;Pecora A;
2003
Abstract
Two different drain field relief architectures, lightly doped drain (LDD) and gate overlapped LDD (GOLDD), for polysilicon TFT have been analyzed and compared to conventional self-aligned (SA) devices. The introduction of LDD regions improves off-current, kink effect and electrical stability if compared to SA devices. However, a parasitic resistance effect is also introduced, thus limiting the benefits of LDD structures. GOLDD architecture overcomes this drawback, but, more importantly, show improved off-current and kink effect and exceptionally high electrical stability. The experimental results have been explained by analyzing the electric field distributions, obtained by two-dimensional numerical simulations, while a new tool to explain hot-carrier induced modifications in polysilicon TFTs was developed.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
