Abstract
For newly developed semiconductors, obtaining high‐performance transistors and identifying carrier mobility have been hot and important issues. Here, large‐area fabrications and thorough analysis of InGaZnO transistors with enhanced current by simple encapsulations are reported. The enhancement in the drain current and on–off ratio is remarkable in the long‐channel devices (e.g., 40 times in 200 µm long transistors) but becomes much less pronounced in short‐channel devices (e.g., 2 times in 5 µm long transistors), which limits its application to the display industry. Combining gated four‐probe measurements, scanning Kelvin‐probe microscopy, secondary ion mass spectrometry, X‐ray photoelectron spectroscopy, and device simulations, it is revealed that the enhanced apparent mobility up to several tens of times is attributed to the stabilized hydrogens in the middle area forming a degenerated channel area while that near the source‐drain contacts are merely doped, which causes artifact in mobility extraction. The studies demonstrate the use of hydrogens to remarkably enhance performance of oxide transistors by inducing a new mode of device operation. Also, this study shows clearly that a thorough analysis is necessary to understand the origin of very high apparent mobilities in thin‐film transistors or field‐effect transistors with advanced semiconductors.
Highlights
For newly developed semiconductors, obtaining high-performance transistors and identifying carrier mobility have been hot and important issues
To understand the origin of enhanced current and why it is only significant in long-channel devices, we investigated the current–voltage characteristics, capacitance–voltage relations, gated four-probe measurement (GFP) for potentials, scanning Kelvin probe microscope (SKPM) for surface, 2D
Contact resistance RC of IGZO thin-film transistors (TFTs) is about 114 kΩ and is similar with RTOT of IGZO-H TFTs. These results suggest that, for IGZO-H devices, the resistance of the contact area and not that of the channel area is dominant in determining RTOT
Summary
For newly developed semiconductors, obtaining high-performance transistors and identifying carrier mobility have been hot and important issues. The various investigations give highly consistent understandings for the origin of ultrahigh apparent mobility, demonstrate the necessity of critical analysis for high-performance TFT or field-effect transistor (FET), and provide a partially doped device structure with enhanced on–off ratio and operational reliability.
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