Optimization of two major interfaces in MoS2 FETs with low frequency noise analysis

The two interfaces in direct contact with the channel are the main factors affecting the performance of MoS 2 FETs. They are the source–drain electrode contacts and the interface between the channel and the gate dielectric material. As carriers move through the channel, they may fluctuate if they en...

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Bibliographic Details
Published in:Journal of the Korean Physical Society 2023-06, Vol.82 (11), p.1098-1104
Main Authors: Ji, Hyunjin, Choi, Dong-Hwan, Ahn, Byung-wook
Format: Article
Language:English
Subjects:
Boron nitride
Carrier mobility
Contact resistance
Dielectrics
Electric fields
Electrodes
Frequency analysis
Indium
Interfacial properties
LF noise
Low dimensional semiconductors
Low temperature
Mathematical and Computational Physics
Molybdenum disulfide
Optimization
Original Paper - Condensed Matter
Particle and Nuclear Physics
Performance degradation
Physics
Physics and Astronomy
Scattering
Semiconductor devices
Semiconductor materials
Theoretical
Threshold voltage
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Summary:The two interfaces in direct contact with the channel are the main factors affecting the performance of MoS 2 FETs. They are the source–drain electrode contacts and the interface between the channel and the gate dielectric material. As carriers move through the channel, they may fluctuate if they encounter a non-uniform electrostatic field. Carrier fluctuations are a major cause of performance degradation in semiconductor devices and circuits, resulting from delayed turn-on in the channel and low carrier mobility. This issue is becoming increasingly pronounced as low-dimensional semiconductor materials are used or as devices are miniaturized to an extreme extent. In this study, we utilized low-temperature deposited indium electrodes and hexagonal boron nitride( h -BN) as gate dielectric materials in MoS 2 devices, aiming to minimize interfacial defects. The In-MoS 2 / h -BN device exhibited negligible contact resistance and interfacial Coulomb scattering, and a remarkably reduced density of dielectric traps, resulting in a negative threshold voltage shift of approximately 60 V and a tenfold improvement in carrier mobility. DC and low frequency noise (LFN) measurements were used to evaluate the impact of interfacial properties of the devices. The LFN modeling demonstrated that interfacial Coulomb scattering was reduced in the low-current region for devices utilizing the indium electrodes. The LFN provided reasonable results compared with the DC analysis, and also detailed information about the behavior of carriers.
ISSN:0374-4884
1976-8524
DOI:10.1007/s40042-023-00825-7