Your search keyword '"Duan, Meng"' showing total 8 results

1. TCAD Framework for HCD Kinetics in Low VD Devices Spanning Full VG/VD Space.

Author

Sharma, Uma, Duan, Meng, Diwakar, Himanshu, Thakor, Karansingh, Wong, Hiu Yung, Motzny, Steve, Dolgos, Denis, and Mahapatra, Souvik

Subjects

*HOT carriers, *PARAMETRIC devices, *ANALYTICAL mechanics, *METAL oxide semiconductor field-effect transistors, *MODULATION-doped field-effect transistors, *DIFFUSION, *LOGIC circuits

Abstract

The time kinetics of hot carrier degradation (HCD) is modeled using a reaction diffusion drift (RDD) framework. It is incorporated into Sentaurus Device TCAD and validated using conduction mode HCD data in n- and p-channel MOSFETs and FinFETs. RDD-enabled TCAD calculates carrier-energy-initiated generation of interface traps (Δ NIT) and the impact of the resulting localized charges on device parametric drift. HCD at various gate (VG) and drain (VD) biases spanning various modes (VG ≤ and > VD) are simulated for low stress VD (< 3 V). The self-heating (SH)-effect-induced temperature (T) increase is invoked for FinFETs. Data from various experiments are analyzed and a wide range of power-law time kinetics slope (n) is explained. [ABSTRACT FROM AUTHOR]

Published

2020

2. Key Issues and Solutions for Characterizing Hot Carrier Aging of Nanometer Scale nMOSFETs.

Author

Duan, Meng, Zhang, Jian Fu, Ji, Zhigang, Zhang, Wei Dong, Kaczer, Ben, and Asenov, Asen

Subjects

*METAL oxide semiconductor field-effect transistors, *NANOSTRUCTURED materials, *BAND gaps, *SILICON, *ELECTRIC fields

Abstract

Silicon bandgap limits the reduction of operation voltage when downscaling device sizes. This increases the electrical field within-a-device and hot carrier aging (HCA) is becoming an important reliability issue again for some CMOS technologies. For nanodevices, there are a number of challenges for characterizing their HCA: the random charge–discharge of traps in gate dielectric causes “within-a-device-fluctuation (WDF),” making the parameter shift uncertain after a given HCA. This can introduce errors when extracting HCA time exponents and it will be shown that the lower envelope of the WDF must be used. Nanodevices also have substantial device-to-device variation (DDV) and multiple tests are needed for evaluating their standard deviation ( $\sigma )$ and mean value ( $\mu $ ). Repeating the time-consuming HCA tests is costly and a voltage-step-stress method is applied to reduce the number of tests by 80%. For a given number of devices under tests (DUTs), there is a little information on the accuracy of the extracted $\sigma $ and $\mu $ . We will develop a method to provide this information, based on the defect-centric model. For 40 DUTs with an average of ten traps per device, the extracted $\mu $ and $\sigma $ has an accuracy of ±14% and ±24%, respectively, with a 95% confidence. [ABSTRACT FROM PUBLISHER]

Published

2017

3. Insight Into Electron Traps and Their Energy Distribution Under Positive Bias Temperature Stress and Hot Carrier Aging.

Author

Duan, Meng, Zhang, Jian Fu, Ji, Zhigang, Zhang, Wei Dong, Vigar, David, Asenov, Asen, Gerrer, Louis, Chandra, Vikas, Aitken, Rob, and Kaczer, Ben

Subjects

*ELECTRON traps, *SPECTRAL energy distribution, *HOT carriers, *STATIC random access memory chips, *ELECTRIC discharges

Abstract

The access transistor of SRAM can suffer both positive bias temperature instability (PBTI) and hot carrier aging (HCA) during operation. The understanding of electron traps (ETs) is still incomplete and there is little information on their similarity and differences under these two stress modes. The key objective of this paper is to investigate ETs in terms of energy distribution, charging and discharging properties, and generation. We found that both PBTI and HCA can charge ETs which center at 1.4 eV below conduction band ( Ec ) of high-k dielectric, agreeing with theoretical calculation. For the first time, clear evidences are presented that HCA generates new ETs, which do not exist when stressed by PBTI. When charged, the generated ETs’ peak is 0.2 eV deeper than that of preexisting ETs. In contrast with the power law kinetics for charging the preexisting ETs, filling the generated ETs saturates in seconds, even under an operation bias of 0.9 V. ET generation shortens device lifetime and must be included in modeling HCA. A cyclic and antineutralization ETs model is proposed to explain PBTI and HCA degradation, which consists of preexisting cyclic ETs, generated cyclic ETs, and antineutralization ETs. [ABSTRACT FROM AUTHOR]

Published

2016

4. Development of a Technique for Characterizing Bias Temperature Instability-Induced Device-to-Device Variation at SRAM-Relevant Conditions.

Author

Duan, Meng, Zhang, Jian Fu, Ji, Zhigang, Zhang, Wei Dong, Kaczer, Ben, Schram, Tom, Ritzenthaler, Romain, Groeseneken, Guido, and Asenov, Asen

Subjects

*STATIC random access memory, *ELECTRONIC noise, *METAL oxide semiconductor field-effect transistors, *ELECTRIC circuit analysis, *RANDOM access memory

Abstract

SRAM is vulnerable to device-to-device variation (DDV), since it uses minimum-sized devices and requires device matching. In addition to the as-fabricated DDV at time-zero, aging induces a time-dependent DDV (TDDV). Bias temperature instability (BTI) is a dominant aging process. A number of techniques have been developed to characterize the BTI, including the conventional pulse- \(I\) – \(V\) , random telegraph noises, time-dependent defect spectroscopy, and TDDV accounting for the within-device fluctuation. These techniques, however, cannot be directly applied to SRAM, because their test conditions do not comply with typical SRAM operation. The central objective of this paper is to develop a technique suitable for characterizing both the negative BTI (NBTI) and positive BTI (PBTI) in SRAM. The key issues addressed include the SRAM relevant sensing Vg, measurement delay, capturing the upper envelope of degradation, sampling rate, and measurement time window. The differences between NBTI and PBTI are highlighted. The impact of NBTI and PBTI on the cell-level performance is assessed by simulation, based on experimental results obtained from individual devices. The simulation results show that, for a given static noise margin, test conditions have a significant effect on the minimum operation bias. [ABSTRACT FROM PUBLISHER]

Published

2014

5. New Analysis Method for Time-Dependent Device-To-Device Variation Accounting for Within-Device Fluctuation.

Author

Duan, Meng, Zhang, Jian F., Ji, Zhigang, Zhang, Wei Dong, Kaczer, Ben, Schram, Tom, Ritzenthaler, Romain, Groeseneken, Guido, and Asenov, Asen

Subjects

*VARIABILITY (Psychometrics), *NANOSTRUCTURED materials, *DATA acquisition systems, *STATISTICAL correlation, *FLUCTUATIONS (Physics)

Abstract

Variability of nanometer-size devices is a major challenge for circuit design. Apart from the as-fabricated variability, the postfabrication degradation introduces a time-dependent variability, originating from statistical distribution of charge location and number. The existing characterization techniques do not always capture the maximum degradation. Some of them does not separate the device-to-device variation from the charging fluctuation within the same device, either. The objective of this paper is to develop a new analysis method for characterizing time-dependent device-to-device variation, accounting for within-device fluctuation (TVF). The TVF captures the maximum degradation, separate device-to-device variation from within-device fluctuation, and reduce the data points by three orders of magnitude. It is shown that the popular data acquisition at discrete time points does not capture the fluctuation well and drain current must be measured continuously. The TVF shows that degradation has two components—a fluctuation with time and one whose discharge is not observed under a given bias. Although both of them increase with stress time, the correlation between them is weak, indicating two different origins. [ABSTRACT FROM AUTHOR]

Published

2013

6. New Insights Into Defect Loss, Slowdown, and Device Lifetime Enhancement.

Author

Duan, Meng, Zhang, Jian Fu, Ji, Zhigang, Zhang, Wei Dong, Kaczer, Ben, De Gendt, Stefan, and Groeseneken, Guido

Subjects

*ELECTRIC potential, *HIGH voltages, *METAL oxide semiconductor field-effect transistors, *CHARGE coupled devices, *MANUFACTURING defects, *PRODUCT liability

Abstract

Defects in gate oxide cause breakdown and shorten device lifetime. Early works mainly focused on generation process that converts a precursor into a charged defect. Although it can be neutralized through “recovery,” the defect is still there and will recharge when resuming stress. Recently, we have shown that this is not always the case and some defects can be lost, but a detailed investigation is missing. The central objective of this work is to accurately define and extract the loss, separate it from slowdown, and evaluate their enhancement of device lifetime. Loss is defined as elimination of defects, while slowdown means that recharging a “hardened” precursor takes longer than charging a fresh one. Clear evidences show that losses originate from permanent components, i.e., generated interface states and antineutralization positive charges, while slowdown occurs to both permanent and recoverable components. Loss is thermally accelerated, but slowdown of recoverable component is not. This improved understanding adds slowdown and losses to the existing framework for defects. For the first time, we report that the losses and slowdown enhance device lifetime by a factor of 2.6–4.3, for an allowed threshold voltage shift of 20–45 mV. [ABSTRACT FROM AUTHOR]

Published

2013

7. Reliable Time Exponents for Long Term Prediction of Negative Bias Temperature Instability by Extrapolation.

Author

Gao, Rui, Manut, Azrif B., Ji, Zhigang, Ma, Jigang, Duan, Meng, Zhang, Jian Fu, Franco, Jacopo, Hatta, Sharifah Wan Muhamad, Zhang, Wei Dong, Kaczer, Ben, Vigar, David, Linten, Dimitri, and Groeseneken, Guido

Subjects

*EFFECT of temperature on metal oxide semiconductor field-effect transistors, *EXTRAPOLATION, *ENGINEERING standards, *HOLES (Electron deficiencies), *POINT defects

Abstract

To predict the negative bias temperature instability (NBTI) toward the end of pMOSFETs’ ten years lifetime, power-law-based extrapolation is the industrial standard method. The prediction accuracy crucially depends on the accuracy of time exponents, n. n reported by early work spreads in a wide range and varies with measurement conditions, which can lead to unacceptable errors when extrapolated to ten years. The objective of this paper is to find how to make n extraction independent of measurement conditions. After removing the contribution from as-grown hole traps, a new method is proposed to capture the generated defects (GDs) in their entirety. n extracted by this method is around 0.2 and insensitive to measurement conditions for the four fabrication processes we tested. The model based on this method is verified by comparing its prediction with measurements. Under ac operation, the model predicts that the GD can contribute to ~90% of NBTI at ten years. [ABSTRACT FROM PUBLISHER]

Published

2017

8. An Investigation on Border Traps in III–V MOSFETs With an In0.53Ga0.47As Channel.

Author

Ji, Zhigang, Zhang, Xiong, Franco, Jacopo, Gao, Rui, Duan, Meng, Zhang, Jian Fu, Zhang, Wei Dong, Kaczer, Ben, Alian, Alireza, Linten, Dimitri, Zhou, Daisy, Collaert, Nadine, De Gendt, Stefan, and Groeseneken, Guido

Subjects

*METAL oxide semiconductor field-effect transistors, *COMPLEMENTARY metal oxide semiconductors, *INDIUM gallium arsenide, *QUANTUM wells, *ATOMIC layer deposition

Abstract

Continuing CMOS performance scaling requires developing MOSFETs of high-mobility semiconductors and InGaAs is a strong candidate for n-channel. InGaAs MOSFETs, however, suffer from high densities of border traps, and their origin and impact on device characteristics are poorly understood at present. In this paper, the border traps in nMOSFETs with an In0.53Ga0.47As channel and Al2O3 gate oxide are investigated using the discharging-based energy profiling technique. By analyzing the trap energy distributions after charging under different gate biases, two types of border traps together with their energy distributions are identified. Their different dependences on temperature and charging time support that they have different physical origins. The impact of channel thickness on them is also discussed. Identifying and understanding these different types of border traps can assist in the future process optimization. Moreover, border trap study can yield crucial information for long-term reliability modeling and device time-to-failure projection. [ABSTRACT FROM AUTHOR]

Published

2015