M. Tang scite author profile

M. Tang

5Publications

108Citation Statements Received

35Citation Statements Given

How they've been cited

228

105

How they cite others

Affiliations

National Chung Hsing University, Powertech Technology (Taiwan), Liaoning Technical University

Publications

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Ferroelectric gate tunnel field-effect transistors with low-power steep turn-on

Lee

Wei

Lin

et al. 2014

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Using a ferroelectric PbZrTiO3 gate stack, the range of the steep subthreshold swing in tunnel field-effect transistors was extended by 3.5 orders of magnitude demonstrating an improvement in the swing (by approximately double the slope). The drain conductance (gd) shows only 16% enhancement with large V DS (∼−1.5V) indicates internal voltage amplification with ferroelectric negative capacitance effect beneficial to small lateral drain-source bias voltages (−0.1 V). The concept of coupling the ferroelectric polarization is proposed. The power consumption is also discussed in low-power applications of steep subthreshold slope devices.

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Prospects for ferroelectric HfZrOx FETs with experimentally CET=0.98nm, SSfor=42mV/dec, SSrev=28mV/dec, switch-off 0.2V, and hysteresis-free strategies

Lee

Chen

Liu

et al. 2015

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Ferroelectric negative capacitance hetero-tunnel field-effect-transistors with internal voltage amplification

Lee

Lin

Wei

et al. 2013

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Extremely Steep Switch of Negative-Capacitance Nanosheet GAA-FETs and FinFETs

Lee

Chen

Liao

et al. 2018

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Steep Switching of In0.18Al0.82N/AlN/GaN MIS-HEMT (Metal Insulator Semiconductor High Electron Mobility Transistors) on Si for Sensor Applications

Chen

Tang

et al. 2018

Sensors

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InAlN/Al/GaN high electron mobility transistors (HEMTs) directly on Si with dynamic threshold voltage for steep subthreshold slope (<60 mV/dec) are demonstrated in this study, and attributed to displacement charge transition effects. The material analysis with High-Resolution X-ray Diffraction (HR-XRD) and the relaxation by reciprocal space mapping (RSM) are performed to confirm indium barrier composition and epitaxy quality. The proposed InAlN barrier HEMTs exhibits high ON/OFF ratio with seven magnitudes and a steep threshold swing (SS) is also obtained with SS = 99 mV/dec for forward sweep and SS = 28 mV/dec for reverse sweep. For GaN-based HEMT directly on Si, this study displays outstanding performance with high ON/OFF ratio and SS < 60 mV/dec behaviors.

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M. Tang

Ferroelectric gate tunnel field-effect transistors with low-power steep turn-on

Prospects for ferroelectric HfZrOx FETs with experimentally CET=0.98nm, SSfor=42mV/dec, SSrev=28mV/dec, switch-off 0.2V, and hysteresis-free strategies

Ferroelectric negative capacitance hetero-tunnel field-effect-transistors with internal voltage amplification

Extremely Steep Switch of Negative-Capacitance Nanosheet GAA-FETs and FinFETs

Steep Switching of In0.18Al0.82N/AlN/GaN MIS-HEMT (Metal Insulator Semiconductor High Electron Mobility Transistors) on Si for Sensor Applications

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