Conduction and Electric Field Effect in Ultra-Thin Tungsten Films

Zouw, Kees van der; Aarnink, Antonius A.I.; Schmitz, Jurriaan; Kovalgin, Alexeij Y.

doi:10.1109/tsm.2020.2976886

IEEE Trans. Semicond. Manufact.

2020

DOI: 10.1109/tsm.2020.2976886

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Conduction and Electric Field Effect in Ultra-Thin Tungsten Films

Kees van der Zouw¹,

Antonius A.I. Aarnink²,

Jurriaan Schmitz³

et al.

Abstract: Ultra-thin tungsten films were prepared using hotwire assisted atomic layer deposition. The film thickness ranged from 2.5 to 10 nm, as determined by spectroscopic ellipsometry and verified by scanning electron microscopy. The films were implemented in conventional Van der Pauw and circular transmission line method (CTLM) test structures, to explore the effect of film thickness on the sheet and contact resistance, temperature coefficient of resistance (TCR), and external electric field applied. All films exhib… Show more

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Cited by 2 publications

References 49 publications

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Channel Mobility Model of Nano-Node MOSFETs Incorporating Drain-and-Gate Electric Fields

Chao

Huang

et al. 2022

Crystals

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A novel channel mobility model with two-dimensional (2D) aspect is presented covering the effects of source/drain voltage (VDS) and gate voltage (VGS), and incorporating the drift and diffusion current on the surface channel at the nano-node level, at the 28-nm node. The effect of the diffusion current is satisfactory to describe the behavior of the drive current in nano-node MOSFETs under the operations of two-dimensional electrical fields. This breakthrough in the model’s establishment opens up the integrity of long-and-short channel devices. By introducing the variables VDS and VGS, the mixed drift and diffusion current model effectively and meaningfully demonstrates the drive current of MOSFETs under the operation of horizontal, vertical, or 2D electrical fields. When comparing the simulated and experimental consequences, the electrical performance is impressive. The error between the simulation and experiment is less than 0.3%, better than the empirical adjustment required to issue a set of drive current models.

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Channel Mobility Model of Nano-Node MOSFETs Incorporating Drain-and-Gate Electric Fields

Chao

Huang

et al. 2022

Crystals

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show abstract

A Comparative Investigation on the Microstructure and Thermal Resistance of W-Film Sensor Using dc Magnetron Sputtering and High-Power Pulsed Magnetron Sputtering

Huan

Wang

et al. 2023

Magnetochemistry

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Traditional dc magnetron sputtering has a low ionization rate when preparing metallic thin films. With the development of thin film science and the market demand for thin film material applications, it is necessary to improve the density of magnetron-sputtered films. High-power pulsed magnetron sputtering (HiPIMS) technology is a physical vapor deposition technology with a high ionization rate and high energy. Therefore, in this work, HiPIMS was applied to prepare metallic tungsten films and compare the surface morphology and microstructure of metallic tungsten films deposited using HiPIMS and dc magnetron sputtering (dcMS) technology under different pulse lengths, as well as related thermal resistance performance, followed by annealing treatment for comparative analysis. We used AFM, SEM, XRD, and plasma characterization testing to comprehensively analyze the changes in the TCR value, stability, repeatability and other related performance of the metallic tungsten thin-film sensor deposited by the HiPIMS technology. It was determined that the thin film prepared by the HiPIMS method is denser, with fewer defects, and the film sensor was stable. The 400 °C annealed sample prepared using HiPIMS with a 100 μs pulse length reaches the largest recorded TCR values of 1.05 × 10−3 K−1. In addition, it shows better stability in repeated tests.

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Conduction and Electric Field Effect in Ultra-Thin Tungsten Films

Cited by 2 publications

References 49 publications

Channel Mobility Model of Nano-Node MOSFETs Incorporating Drain-and-Gate Electric Fields

Channel Mobility Model of Nano-Node MOSFETs Incorporating Drain-and-Gate Electric Fields

A Comparative Investigation on the Microstructure and Thermal Resistance of W-Film Sensor Using dc Magnetron Sputtering and High-Power Pulsed Magnetron Sputtering

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