In this paper, we investigated the hot carrier reliability of two kinds of device with low threshold voltage (LVT) and regular threshold voltage (RVT) in 65 nm CMOS technology. Contrary to the previous report that devices beyond 0.18 μm CMOS technology is dominated by channel hot carrier(CHC) stress rather than drain avalanche hot carrier(DAHC) stress, both of LVT and RVT devices showed that their degradation is dominated by DAHC stress. It is also shown that in case of LVT devices, contribution of interface trap generation to the device degradation is greater under DAHC stress than CHC stress, while there is little difference for RVT devices.
We have investigated the effect of electrical properties of amorphous InGaZnO thin filmtransistors (a-IGZO TFTs) by post thermal annealing in O2 ambient.The post-annealed in O2 ambienta-IGZOTFT is found to be more stable to be used for oxide-based TFT devices, and has betterperformance, such as the on/off current ratios, sub-threshold voltage gate swing, and, as well asreasonable threshold voltage, than others do. The interface trap density is controlled to achieve theoptimum value of TFT transfer and output characteristics. The device performance is significantlyaffected by adjusting the annealing condition. This effect is closely related with the modulation annealingmethod by reducing the localized trapping carriers and defect centers at the interface or in the channellayer.
In this paper, flicker noise characteristic and channel hot carrier degradation of NMOSFETs with plasma nitrided oixde (PNO) and thermally nitrided oxide (TNO) are analyzed in depth. Compared with NMOSFET with TNO, flicker noise characteristic of NMOSFET with PNO is improved significantly because nitrogen density in PNO near the Si/SiO2 interface is less than that in TNO. However, device degradation of NMOSFET with PNO by channel hot carrier stress is greater than that with TNO although PMOSFET with PNO showed greater immunity to NBTI degradation than that with TNO in previous study. Therefore, concurrent investigation of the reliability as well as low frequency noise characteristics of NMOSFET and PMOSFET is required for the development of high performance analog MOSFET technology.
In this paper, we investigated an anomalous hump phenomenon under the positive bias stress in p-type LTPS TFTs. The devices with inferior electrical performance also show larger hump phenomenon. which can be explained by the sub-channel induced from trapped electrons under thinner gate oxide region. We can confirm that the devices with larger hump have larger interface trap density (Dit) and grain boundary trap density (Ntrap) extracted by low-high frequency capacitance method and Levinson-Proano method, respectively. From the C-V with I-V transfer characteristics, the trapped electrons causing hump seem to be generated particularly from the S/D and gate overlapped region. Based on these analysis, the major cause of an anomalous hump phenomenon under the positive bias stress in p-type poly-Si TFTs is explained by the GIDL occurring in the S/D and gate overlapped region and the traps existing in the channel edge region where the gate oxide becomes thinner, which can be inferred by the fact that the magnitude of the hump is dependent on the average trap densities.