Abstract
Co-sputtering of SiO2 and high-κ Ta2O5 was used to make multicomponent gate dielectric stacks for In-Ga-Zn-O thin-film transistors (IGZO TFTs) under an overall low thermal budget (T = 150 °C). Characterization of the multicomponent layers and of the TFTs working characteristics (employing them) was performed in terms of static performance, reliability, and stability to understand the role of the incorporation of the high-κ material in the gate dielectric stack. It is shown that inherent disadvantages of the high-κ material, such as poorer interface properties and poor gate insulation, can be counterbalanced by inclusion of SiO2 both mixed with Ta2O5 and as thin interfacial layers. A stack comprising a (Ta2O5)x(SiO2)100 − x film with x = 69 and a thin SiO2 film at the interface with IGZO resulted in the best performing TFTs, with field-effect mobility (µFE) ≈ 16 cm2·V−1·s−1, subthreshold slope (SS) ≈ 0.15 V/dec and on/off ratio exceeding 107. Anomalous Vth shifts were observed during positive gate bias stress (PGBS), followed by very slow recoveries (time constant exceeding 8 × 105 s), and analysis of the stress and recovery processes for the different gate dielectric stacks showed that the relevant mechanism is not dominated by the interfaces but seems to be related to the migration of charged species in the dielectric. The incorporation of additional SiO2 layers into the gate dielectric stack is shown to effectively counterbalance this anomalous shift. This multilayered gate dielectric stack approach is in line with both the large area and the flexible electronics needs, yielding reliable devices with performance suitable for successful integration on new electronic applications.
Highlights
Rutherford backscattering spectrometry (RBS) analysis was performed on the multicomponent films sputtered with different powers applied to the Ta2 O5 target
Multicomponent gate dielectric stacks comprised of both SiO2 and high-κ Ta2 O5 were explored for oxide TFTs with low thermal budgets, compatible with flexible electronics (T = 150 ◦ C)
Counterclockwise hysteresis of the transfer curves and anomalous Vth shifts seen during positive gate bias stress (PGBS) were, unexpectedly, higher in magnitude for SiO2 richer compositions, with ∆Vth ≈ −102 V and −30 V, after 1 h stress, for the T39 S61 and the T75 S25 compositions, respectively
Summary
Amorphous oxide (AO) thin films have greatly progressed in a relatively short time, having found market application in the display industry where materials such as indiumgallium-zinc oxide (IGZO) appear as an advantageous alternative to Si technologies [1,2] Besides conventional electronics, their characteristics make them suitable for concepts such as transparent and flexible electronics [3,4,5] or even paper electronics [6,7,8,9], allowing for interesting applications in fields such as medical, security and item tracking [10,11], crucial under the scope of the Internet of Things (IoT). Lower annealing temperatures unavoidably result in poorer device performance and stability When considering these lower annealing temperatures the IGZO properties are known to be strongly related to its processing conditions [12] and adjustment of the cation ratio.
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