Your search keyword '"Chen, Kevin J."' showing total 41 results

1. GaN on Engineered Bulk Si (GaN-on-EBUS) Substrate for Monolithic Integration of High-/Low-Side Switches in Bridge Circuits.

Author

Lyu, Gang, Wei, Jin, Song, Wenjie, Zheng, Zheyang, Zhang, Li, Zhang, Jie, Feng, Sirui, and Chen, Kevin J.

Subjects

BRIDGE circuits, SWITCHING circuits, GALLIUM nitride, MODULATION-doped field-effect transistors, ION implantation, MOLECULAR beam epitaxy, LOGIC circuits, EPITAXY

Abstract

A cost-effective engineered bulk silicon (EBUS) substrate technology is presented, featuring p-n junction implemented on bulk Si substrates using mainstream ion implantation and thermal annealing processes. Standard p-GaN/AlGaN/GaN heterostructures are successfully grown on the EBUS substrate and used to fabricate 200-V enhancement-mode p-GaN gate HEMTs. By creating deep trenches in the EBUS substrate to isolate the local P+ silicon regions underneath the high-side (HS) and low-side (LS) power switches, adverse effects (e.g., back-gating and dynamic ON-resistance degradation) in the use of conventional bulk Si substrate are all eliminated. The mechanism of crosstalk suppression in the GaN-on-EBUS platform is revealed in comparison with conventional GaN-on-Si platform and verified by a series of designed tests. [ABSTRACT FROM AUTHOR]

Published

2022

2. ON-Resistance Analysis of GaN Reverse-Conducting HEMT With Distributive Built-In SBD.

Author

Wei, Jin, Zhang, Li, Zheng, Zheyang, Song, Wenjie, Yang, Song, and Chen, Kevin J.

Subjects

SCHOTTKY barrier diodes, GALLIUM nitride, POWER transistors

Abstract

Recently, a GaN reverse-conducting high-electron-mobility transistor (RC-HEMT) has been demonstrated. The RC-HEMT features built-in distributive Schottky contacts, which provide a low-loss freewheeling path. The RC-HEMT offers the same functionality as an HEMT/Schottky barrier diode (SBD) pair, but consumes much less chip area, thus its ${R}_{ \mathrm{\scriptscriptstyle ON}}$ (ON-resistance $\times $ total device width) is significantly reduced. Theoretically, ${R}_{ \mathrm{\scriptscriptstyle ON}}$ of the RC-HEMT can approach that of an HEMT. In practice, due to certain geometry limitations, ${R}_{ \mathrm{\scriptscriptstyle ON}}$ of an RC-HEMT lies between an HEMT/SBD pair and a single HEMT. This work investigates the factors that influence ${R}_{ \mathrm{\scriptscriptstyle ON}}$ of the RC-HEMT using both experimental measurements and numerical simulations. It is found that ${R}_{ \mathrm{\scriptscriptstyle ON}}$ of the RC-HEMT is strongly affected by the geometry of the source and channel regions, where HEMT sections and SBD sections are interdigitally distributed. With coarse patterning of these regions, ${R}_{ \mathrm{\scriptscriptstyle ON}}$ of the RC-HEMT is close to the HEMT/SBD pair. Through proper geometry scaling, ${R}_{ \mathrm{\scriptscriptstyle ON}}$ of RC-HEMT is reduced and approaches that of HEMT. [ABSTRACT FROM AUTHOR]

Published

2022

3. High-Performance Ultrathin-Barrier AlGaN/GaN Hybrid Anode Diode With Al₂O₃ Gate Dielectric and In Situ Si₃N₄-Cap Passivation.

Author

Zhu, Liyang, Zhou, Qi, Yang, Xiu, Lei, Jiacheng, Chen, Kuangli, Luo, Zhihua, Huang, Peng, Zhou, Chunhua, Chen, Kevin J., and Zhang, Bo

Subjects

PASSIVATION, DIELECTRICS, ANODES, WIDE gap semiconductors, DIODES, MODULATION-doped field-effect transistors, ALUMINUM gallium nitride, METAL semiconductor field-effect transistors

Abstract

In this article, an ultrathin-barrier (UTB) AlGaN/GaN diode featuring metal–insulator–semiconductor (MIS)-gated hybrid anode (MG-HAD) and in situ Si3N4 cap passivation is demonstrated. The intrinsic turn-on voltage (VON) as low as 0.31 V determined by the as-grown AlGaN-barrier thickness (4.9 nm) is obtained and the VON exhibits excellent uniformity. More importantly, benefit from the MIS-gated hybrid anode structure, the UTB MG-HAD features good thermal stability in reverse blocking capability. The device delivers a substantially low leakage less than 1~μm/mm at −300 V at high temperature (HT) up to 200 °C, which is more than 100 × lower than that in the reference device w/o gate dielectric. Besides, the device exhibits respectably improved dynamic characteristics due to the incorporation of in situ Si3N4-cap passivation layer and remote plasma pretreatment (RPP) prior to Al2O3 gate dielectric deposition. The UTB MG-HAD featuring precisely VON modulation and low reverse leakage is of great interest for power electronic applications. [ABSTRACT FROM AUTHOR]

Published

2020

4. Superjunction IGBT With Conductivity Modulation Actively Controlled by Two Separate Driving Signals.

Author

Wei, Jin, Zhang, Meng, and Chen, Kevin J.

Subjects

BIPOLAR transistors, CARRIER density, METAL oxide semiconductor field-effect transistors, LOGIC circuits

Abstract

A dual-gate superjunction insulated gate bipolar transistor (IGBT) (DG-SJ-IGBT) is proposed and studied with numerical TCAD simulations. The new structure utilizes the superjunction structure as a controlling port for the strength of conductivity modulation inside the IGBT, so that a low VON is obtained by a strong conductivity modulation during ON-state and a near-unipolar turn-off is achieved by removing the minority carriers before the turn-off event. For this purpose, the p-pillar in the DG-SJ-IGBT is connected to the p-body using a built-in p-channel MOSFET. The primary gate and the auxiliary gate (i.e., gate of p-MOSFET) are controlled by two separate driving signals. In the IGBT’s ON-state, the p-MOSFET disconnects the p-pillar, enabling full conductivity-modulated bipolar conduction and a consequent low VON. As a well-known issue, conductivity modulation is accompanied by significant additional turn-off loss (EOFF). To overcome this issue, the DG-SJ-IGBT takes advantage of the p-pillar which extends through the entire drift region. Before the IGBT’s turn-off event, the p-MOSFET electrically grounds the p-pillar to the p-body. The grounded p-pillar serves as a hole extractor, suppresses the minority carrier density throughout the depth of the drift region, and brings the device into a near-unipolar conduction mode. Thus, a near-unipolar turn-off can be obtained, resulting in a low EOFF. [ABSTRACT FROM AUTHOR]

Published

2020

5. Hole-Induced Degradation in E-Mode GaN MIS-FETs: Impact of Substrate Terminations.

Author

Hua, Mengyuan, Yang, Song, Wei, Jin, Zheng, Zheyang, He, Jiabei, and Chen, Kevin J.

Subjects

THRESHOLD voltage, METAL oxide semiconductor field-effect transistors, ELECTRONS

Abstract

We conducted reliability characterization under reverse-bias stress (i.e., stress at OFF-state with high VDS) on the E-mode GaN metal–insulator–semiconductor field-effect-transistors (MIS-FETs) with various substrate terminations. The MIS-FETs with floating substrate (FS) show worse threshold voltage (VTH) stability than that with a grounded substrate. A non monotonic dependence of VTH shifts and OFF-state time-to-breakdown (tbd) on the positive substrate bias (Vsub) was also observed. The underlying mechanisms are the different impacts of positive Vsub on the drift of electrons and holes during the long-term stress. An important indication is that positive-biased and FS terminations should be restricted at OFF-state in order to obtain good VTH stability in applications of the GaN MIS-FET. [ABSTRACT FROM AUTHOR]

Published

2020

6. Special Issue on Reliability.

Author

Mahapatra, Souvik, Chen, Kevin J., Kaczer, Ben, Pancheri, Lucio, Rosenbaum, Elyse, Mouli, Chandra, Wong, Hei, Kerber, Andreas, Monzio Compagnoni, Christian, Koval, Randy, Meneghesso, Gaudenzio, Sheridan, David, Ramey, Stephen, Wang, Runsheng, and Stathis, Jim

Subjects

*RELIABILITY in engineering, *MANUFACTURING processes, *SEMICONDUCTOR technology, *AUTHOR-reader relationships, *TIME measurements

Abstract

Reliability is an important consideration during semiconductor technology development, which ensures that the performances of devices, circuits, and systems are maintained over a specified period of time, leading to successful products. Device reliability is at the core of overall product reliability, which continues to remain an important area of research and has attracted the attention of IEEE Transactions on Electron Devices (T-ED) authors and readers throughout the years. Device reliability can be classified into two broad areas: gradual drift of device performance over time or sudden failure, and both are of importance for logic, memory, RF, and power devices. Different aspects of device reliability are usually reported, such as the development of electrical or physical characterization methods, investigation and modeling of a particular phenomenon, impact of material and processes on reliability, and development of reliability tolerant technologies. [ABSTRACT FROM AUTHOR]

Published

2019

7. Investigation of Dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ Under Switching Operation in Schottky-Type p-GaN Gate HEMTs.

Author

Wang, Yuru, Wei, Jin, Yang, Song, Lei, Jiacheng, Hua, Mengyuan, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, GATES, ELECTRON traps, HIGH temperatures

Abstract

In this paper, systematic characterization and the corresponding suppression strategies of dynamic OFF-state leakage current (${I}_{ \mathrm{\scriptscriptstyle OFF}}$) in Schottky-type p-GaN gate high-electron-mobility transistors (HEMTs) are presented based on fast pulsed ${I}$ – ${V}$ measurement and consecutive switching measurement. It is found that the high ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ under dynamic pulse mode without hole injection is a result of the reduced voltage blocking capabilities (both lateral and vertical) with weaker trapping effect in the buffer, and the dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ induced by ON-state hole injection is caused by further increased lateral conductivity through the buffer from source to drain. The corresponding behaviors under continuous waveforms with different switching conditions are analyzed to identify effective approaches for the suppression of dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ in practical switching operations. A higher temperature is shown to be beneficial to the reduction of the dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ induced by ON-state hole injection. To completely eliminate the dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ caused by ON-state hole injection and minimize the OFF-state power consumption in practical power switching applications, a sufficiently large negative OFF-state gate bias (e.g., ${V}_{\text {GS}, \mathrm{\scriptscriptstyle OFF}}\le -{3}$ V) is recommended in the gate driver turn-off voltage design for the Schottky-type p-GaN gate HEMTs. [ABSTRACT FROM AUTHOR]

Published

2019

8. Frequency- and Temperature-Dependent Gate Reliability of Schottky-Type ${p}$ -GaN Gate HEMTs.

Author

He, Jiabei, Wei, Jin, Yang, Song, Wang, Yuru, Zhong, Kailun, and Chen, Kevin J.

Subjects

THRESHOLD voltage, BREAKDOWN voltage, TELEOLOGY, GATES, RELIABILITY in engineering, ANNEALING of metals, WEIBULL distribution, ELECTRIC breakdown

Abstract

In this paper, we carried out a systematic investigation on gate degradation and the physical mechanism of the Schottky-type ${p}$ -GaN gate HEMTs under positive gate voltage stress. The frequency- and temperature-dependent measurements have been conducted. It is found that the time-dependent gate degradation exhibits weak relevance with frequencies ranging from 10 to 100 kHz under dynamic gate stress and is similar to that in static gate stress. Both the gate breakdown voltage (BV) and mean-time-to-failure (MTTF) show positive temperature dependence. Moreover, the current–voltage (I–V) characteristics and threshold voltage (${V}_{\text {TH}}$) instability of ${p}$ -GaN devices before/after gate degradation are compared and analyzed. The degraded Schottky junction exhibits an ohmic-like gate behavior. It is revealed that under a large gate bias stress, high-energy electrons accelerated in the depletion region of the ${p}$ -GaN layer would promote the formation of defect levels near the metal/ ${p}$ -GaN interface, leading to the initial ${p}$ -GaN layer degradation. The subsequent high gate leakage density could cause the final degradation of the AlGaN barrier. [ABSTRACT FROM AUTHOR]

Published

2019

9. Reverse-Conducting Normally-OFF Double-Channel AlGaN/GaN Power Transistor With Interdigital Built-in Schottky Barrier Diode.

Author

Lei, Jiacheng, Wei, Jin, Tang, Gaofei, Qian, Qingkai, Zhang, Zhaofu, Hua, Mengyuan, Zheng, Zheyang, and Chen, Kevin J.

Subjects

SCHOTTKY barrier diodes, POWER transistors, BREAKDOWN voltage, METAL oxide semiconductor field, WIDE gap semiconductors, THRESHOLD voltage, VARISTORS

Abstract

Low-loss reverse-conducting normally- OFF double-channel AlGaN/GaN power transistor with the built-in Schottky barrier diode (SBD) has been systematically studied. This device features the MOS-gate section and SBD-anode section paralleled to an interdigital layout along the gate width direction. A common access region that conducts current at both forward and reverse ON-states is employed, which is beneficial to reduce the conduction loss. With a MOS-HEMT/SBD finger width of ${4}~\mu \text{m}/2~\mu \text{m}$ and a total width ratio of 2:1, the device exhibits a threshold voltage of +0.8 V at a drain current of ${10}~\mu \text{A}$ /mm and a low forward ON-resistance of $12.1~\Omega \cdot \text {mm}$. The Schottky metal contacts 2-DEG directly, which results in a low reverse turn-on voltage of −0.6 V (at −1 mA/mm) and low reverse ON-state voltage of −1.7 V (at −50 mA/mm). A leakage suppression MOS field plate (FP) is applied to shield the Schottky contact from the strong electric field, leading to a low OFF-state leakage current of 14 nA/mm at +100-V drain bias and a high breakdown voltage (BV) of +698 V. The finger width and the number of fingers should be optimized. A narrow finger width benefits the current sharing at the access region, while the increasing number of fingers introduces more Schottky depletion regions along the gate width direction that degrade ${R}_{ \mathrm{\scriptscriptstyle ON}}$. [ABSTRACT FROM AUTHOR]

Published

2019

10. Performance and VTH Stability in E-Mode GaN Fully Recessed MIS-FETs and Partially Recessed MIS-HEMTs With LPCVD-SiNx/PECVD-SiNx Gate Dielectric Stack.

Author

He, Jiabei, Hua, Mengyuan, Zhang, Zhaofu, and Chen, Kevin J.

Subjects

METAL insulator semiconductors, FIELD-effect transistors, DIELECTRIC devices, ELECTRIC potential, SEMICONDUCTORS

Abstract

In this paper, we carried out a systematic comparison between the enhancement-mode GaN-based fully recessed metal-insulator-semiconductor field-effect transistors (MIS-FETs) and partially recessed MIS-high-electron-mobility transistors (MIS-HEMTs) with the same gate dielectric stack (LPCVD-SiNx/PECVD-SiNx) that has delivered promising long-term reliability and stability. Despite a moderately larger on-resistance (${R}_{ \mathrm{ON}}$), the MIS-FETs deliver superior ${V}_{\text {TH}}$ uniformity and thermal stability. Under long-term gate bias stress, both the MIS-HEMT and MIS-FET deliver similar small positive-bias temperature instability, while the negative-bias temperature instability of the MIS-HEMT is much larger than that of MIS-FET. The MIS-FET also delivers a higher ${V}_{\text {TH}}$ stability than the MIS-HEMT under dynamic gate bias stress. It is suggested that the differences in ${V}_{\text {TH}}$ stability mainly originate from the different spatial separation between the trap states and the conducting channel, with it being larger in MIS-HEMT than in MIS-FET. [ABSTRACT FROM AUTHOR]

Published

2018

11. An Analytical Investigation on the Charge Distribution and Gate Control in the Normally-Off GaN Double-Channel MOS-HEMT.

Author

Wei, Jin, Zhang, Meng, Li, Baikui, Tang, Xi, and Chen, Kevin J.

Subjects

GALLIUM nitride, TWO-dimensional electron gas, LOGIC circuits, SEMICONDUCTOR materials, MODULATION-doped field-effect transistors

Abstract

A systematic analytical investigation of the charge distribution and gate control of the normally-off GaN double-channel MOS-HEMT (DC-MOS-HEMT) is presented in this paper. Compared to conventional GaN MOS-HEMT, the DC-MOS-HEMT features a thin AlN insertion layer (AlN-ISL) below the original two dimensional electron gas (2DEG) channel, thus forming a second channel at the interface between AlN-ISL and the underlying GaN. This paper reveals the impact of the AlN-ISL on the 2DEG distribution and the gate control of the channels. The sensitivity of ${V}_{\text {th}}$ against the recess depth is also analytically studied and is found to be nearly independent of the recess depth as long as the recess is terminated in the upper channel layer. The analytical results are well supported by numerical device simulations, and the physical mechanisms behind these findings are explained along with the analytical investigations. [ABSTRACT FROM AUTHOR]

Published

2018

12. Ultrathin-Barrier AlGaN/GaN Heterostructure: A Recess-Free Technology for Manufacturing High-Performance GaN-on-Si Power Devices.

Author

Huang, Sen, Liu, Xinyu, Wang, Xinhua, Kang, Xuanwu, Zhang, Jinhan, Fan, Jie, Shi, Jingyuan, Wei, Ke, Zheng, Yingkui, Gao, Hongwei, Sun, Qian, Wang, Maojun, Shen, Bo, and Chen, Kevin J.

Subjects

ELECTRON gas, CHEMICAL vapor deposition, METAL insulator semiconductors, POWER transistors, GALLIUM nitride, SEMICONDUCTOR device manufacturing

Abstract

(Al)GaN recess-free normally OFF technology is developed for fabrication of high-yield lateral GaN-based power devices. The recess-free process is achieved by an ultrathin-barrier (UTB) AlGaN/GaN heterostructure that features a natural pinched-off 2-D electron gas channel. The top–down manufacturing technique overcomes the challenges in etching of AlGaN barrier with well-controlled depth and uniformity, which is especially attractive for fabrication of normally OFF GaN-based high-electron-mobility transistors (HEMTs) and metal–insulator–semiconductor HEMTs (MIS-HEMTs) on large-size Si substrate. With SiNx passivation grown by low-pressure chemical-vapor deposition, on-resistance of the UTB-AlGaN/GaN-based power devices can be significantly reduced. High-uniformity low-hysteresis normally OFF HEMTs and Al2O3/AlGaN/GaN MIS-HEMTs are successfully demonstrated on the UTB AlGaN/GaN-on-Si platform. It is also a compelling technology platform for manufacturing high-performance GaN-based lateral power diodes, and normally OFF p-(Al)GaN heterojunction field-effect transistors. [ABSTRACT FROM PUBLISHER]

Published

2018

13. Impact of Substrate Bias Polarity on Buffer-Related Current Collapse in AlGaN/GaN-on-Si Power Devices.

Author

Shu Yang, Chunhua Zhou, Shaowen Han, Jin Wei, Kuang Sheng, and Chen, Kevin J.

Subjects

ELECTRON gas, POWER electronics, SEMICONDUCTOR junctions, ELECTRODIFFUSION, HETEROSTRUCTURES

Abstract

Bulk traps in the high-resistivity buffer stack underneath the 2-dimensional electron gas (2DEG), which can interact with the high vertical electric field at OFF state, impose a critical challenge to the dynamic ON-resistance (RON) of AlGaN/GaN-on-Si power devices. In this paper, the impact of substrate bias polarity on carrier injection/transport and buffer-induced current collapse has been investigated by using ramped and transient back-gating characterizations as well as TCAD simulations. High voltage applied to the conductive Si substrate can modulate 2DEG conductivity through the back-gate effect, whereby the dynamics of both acceptor and donor buffer traps are identified. Distinct buffer trapping and asymmetric vertical leakage under opposite top-to-substratebias polarities have been observed, which are attributed to the fundamentally different carrier injection/transport mechanisms. It is suggested that the energy barrier at the nucleation-layer/Si interface can limit the electron injection from Si substrate into the buffer stack and consequently influence the bufferrelated current collapse. [ABSTRACT FROM AUTHOR]

Published

2017

14. Revealing the Nitridation Effects on GaN Surface by First-Principles Calculation and X-Ray/Ultraviolet Photoemission Spectroscopy.

Author

Zhang, Zhaofu, Qian, Qingkai, Tang, Xi, Hua, Mengyuan, Chen, Kevin J., Li, Baikui, and Huang, Baoling

Subjects

NITRIDATION, ULTRAVIOLET spectroscopy, BAND gaps, VALENCE bands, IONIZATION (Atomic physics)

Abstract

In this paper, we report a systematic study of the nitridation effects on GaN surface by first-principles calculations and X-ray/ultraviolet photoemission spectroscopy (XPS/UPS). According to the calculated electronic structures, two surface bands (i.e., the upper band and the lower band) can be seen within the bandgap for the typical surface configurations that may occur in the experimental condition as a result of surface reconstruction. By the deployment of sufficient nitridation, the energy positions of the lower band are modified toward the valence band by ~1 eV, resulting in the overlapping of the lower surface band with the valence band. Meanwhile, the upper surface band is also modified toward the valence band, but by a smaller amount. The modification to the positions of the surface bands is furthermore manifested by XPS/UPS spectra characterization performed on GaN sample that underwent surface treatment with low-energy remote N2 plasma. The theoretical and experimental results insightfully proclaim the nitridation effects on material properties at atomic level, and support a surface-state ionization model for the GaN band-edge (3.4 eV) emission in metal-AlGaN/GaN Schottky-on-heterojunction diode under forward bias. [ABSTRACT FROM PUBLISHER]

Published

2017

15. Dynamic Degradation in SiC Trench MOSFET With a Floating p-Shield Revealed With Numerical Simulations.

Author

Wei, Jin, Zhang, Meng, Jiang, Huaping, Wang, Hanxing, and Chen, Kevin J.

Subjects

METAL oxide semiconductor field-effect transistors, SILICON carbide, P-type semiconductors, COMPUTER simulation, LOGIC circuits

Abstract

A p-type shield region (p-shield) under the gate trench is typically adopted in a SiC trench MOSFET for achieving a lower oxide field and reverse transfer capacitance ( Crss) . This paper comparatively studies the effects of a grounded p-shield and a floating p-shield. Device simulations using Sentaurus TCAD are carried out in this paper to reveal the devices’ internal dynamics. The floating p-shield can effectively reduce the OFF-state oxide field as a grounded p-shield does, without degrading its static performance. However, after being switched from the OFF-state, the ON-state oxide field in the trench MOSFET with a floating p-shield (FS-MOS) is dramatically elevated. Compared with the trench MOSFET with a grounded p-shield, the FS-MOS also exhibits a higher C{{\text {rss}}} and a consequently slower switching speed. Furthermore, the FS-MOS exhibits a degradation of dynamic R{ \mathrm{ON}} during switching operation. A charge storage mechanism is then presented to explain the dynamics in FS-MOS. Upon a high V{{\text {DS}}} , holes are emitted from the floating p-shield when the parasitic p-n-p structure consisting of p-shield, p-body, and n-region between them is punched through, leaving negative charges in the floating p-shield even when the high V{{\text {DS}}} is removed. Based on this mechanism, the behaviors of the FS-MOS are well explained. [ABSTRACT FROM AUTHOR]

Published

2017

16. GaN-on-Si Power Technology: Devices and Applications.

Author

Chen, Kevin J., Haberlen, Oliver, Lidow, Alex, Tsai, Chun lin, Ueda, Tetsuzo, Uemoto, Yasuhiro, and Wu, Yifeng

Subjects

*ELECTRIC properties of gallium nitride, *POWER electronics, *ELECTRIC switchgear, *WIDE gap semiconductors, *METAL oxide semiconductor field-effect transistor circuits, *HETEROJUNCTIONS

Abstract

In this paper, we present a comprehensive reviewand discussion of the state-of-the-art device technology and application development of GaN-on-Si power electronics. Several device technologies for realizing normally off operation that is highly desirable for power switching applications are presented. In addition, the examples of circuit applications that can greatly benefit from the superior performance of GaN power devices are demonstrated. Comparisonwith other competingpower device technology, such as Si superjunction-MOSFET and SiC MOSFET, is also presented and analyzed. Critical issues for commercialization of GaN-on-Si power devices are discussed with regard to cost, reliability, and ease of use. [ABSTRACT FROM AUTHOR]

Published

2017

17. Characterization of Static and Dynamic Behaviors in AlGaN/GaN-on-Si Power Transistors With Photonic-Ohmic Drain.

Author

Tang, Xi, Li, Baikui, Zhang, Zhaofu, Tang, Gaofei, Wei, Jin, and Chen, Kevin J.

Subjects

POWER transistors, PHOTONICS, OHMIC contacts, ELECTRON traps, PHOTONS

Abstract

In this paper, static and dynamic performances of an AlGaN/GaN-on-Si power FET utilizing the integrated photonic-ohmic drain (PODFET) were systematically investigated. The operational mechanisms of the PODFET, including both the conditions of photon generation and the related physical processes, were explained. The dynamic switching tests were carried out under two types of hard switching conditions. With the photon generation and channel current inherently switched ON and OFF in synchronization, the dynamic performances of the PODFET can be significantly enhanced owing to photon pumping of deep electron traps. In addition, the generated photons were proved to be confined in proximity of the drain terminal without causing adverse effects on the device performances (e.g., the OFF-state leakage degradation). [ABSTRACT FROM PUBLISHER]

Published

2016

18. Proposal of a GaN/SiC Hybrid Field-Effect Transistor for Power Switching Applications.

Author

Wei, Jin, Jiang, Huaping, Jiang, Qimeng, and Chen, Kevin J.

Subjects

GALLIUM nitride, SILICON carbide, FIELD-effect transistors, ELECTRIC properties of gallium nitride, ELECTRIC properties of aluminum gallium nitride

Abstract

A GaN/SiC hybrid field-effect transistor (HyFET) is proposed as a high-voltage power device that provides a high-mobility lateral AlGaN/GaN channel to reduce the channel resistance and a vertical SiC drift region to sustain the high OFF-state voltage. The performance of the HyFET is evaluated by numerical device simulations. Compared with the conventional SiC MOSFET, the HyFET exhibits a greatly reduced R\mathrm{\scriptscriptstyle ON} together with a low C\mathrm{ GD} and low gate charges. The figures of merit Q\mathrm{ G}\times R\mathrm{\scriptscriptstyle ON} and Q\mathrm{ GD}\times R\mathrm{\scriptscriptstyle ON} of the HyFET are dramatically improved. [ABSTRACT FROM AUTHOR]

Published

2016

19. Characterization of Leakage and Reliability of SiNx Gate Dielectric by Low-Pressure Chemical Vapor Deposition for GaN-based MIS-HEMTs.

Author

Hua, Mengyuan, Liu, Cheng, Yang, Shu, Liu, Shenghou, Fu, Kai, Dong, Zhihua, Cai, Yong, Zhang, Baoshun, and Chen, Kevin J.

Subjects

CHEMICAL vapor deposition, GALLIUM nitride, DIELECTRICS research, ELECTRIC leakage, RELIABILITY in engineering

Abstract

In this paper, we systematically investigated the leakage and breakdown mechanisms of the low-pressure chemical vapor deposition (LPCVD) silicon nitride thin film deposited on AlGaN/GaN heterostructures. The LPCVD-SiNx gate dielectric exhibits low leakage and high breakdown electric field. The dominant mechanism of the leakage current through LPCVD-SiNx gate dielectric is identified to be Poole–Frenkel emission at low electric field and Fowler–Nordheim tunneling at high electric field. Both electric-field-accelerated and temperature-accelerated time-dependent dielectric breakdown of the LPCVD-SiNx gate dielectric were also investigated. [ABSTRACT FROM PUBLISHER]

Published

2015

20. Temperature Dependence of the Surface- and Buffer-Induced Current Collapse in GaN High-Electron Mobility Transistors on Si Substrate.

Author

Zhang, Chuan, Wang, Maojun, Xie, Bing, Wen, Cheng P., Wang, Jinyan, Hao, Yilong, Wu, Wengang, Chen, Kevin J., and Shen, Bo

Subjects

MODULATION-doped field-effect transistors, FIELD-effect transistors, HOT carriers, HOT electron transistors, SURFACE states

Abstract

The temperature dependence of current collapse (CC) in AlGaN/GaN high-electron mobility transistors on silicon substrate is studied in this paper. Devices without and with Si3N4 passivation are used to investigate the behavior of surface- and buffer-induced CC, respectively. It is found that the degree of surface-induced CC in unpassivated devices has a weak temperature dependence, which is induced by the cancelling out between enhanced carrier injection based on surface hopping and enhanced emission when the temperature is increased. On the other hand, the degree of buffer-induced CC in the Si3N4 passivated devices is reduced at higher temperature since the energy of hot electrons is reduced due to the phonon scattering and the trapping of hot electrons in the buffer is mitigated. Temperature-dependent transient measurement is also carried out to investigate the recovery process for these two type of CC. Two types of trap levels are identified in the unpassivated and Si3N4 passivated devices, respectively. The trap level $E1$ with an activation energy of 0.08 eV is supposed to be related to the surface trapping, while $E2$ with an activation energy of 0.22 eV is located in the buffer layer. [ABSTRACT FROM AUTHOR]

Published

2015

21. AC-Capacitance Techniques for Interface Trap Analysis in GaN-Based Buried-Channel MIS-HEMTs.

Author

Yang, Shu, Liu, Shenghou, Lu, Yunyou, Liu, Cheng, and Chen, Kevin J.

Subjects

ELECTRIC capacity, METAL insulator semiconductors, ELECTRON mobility, CURRENT-voltage characteristics, THRESHOLD voltage, HETEROJUNCTIONS, SEMICONDUCTOR junctions

Abstract

Effective interface trap characterization approaches are indispensable in the development of gate stack and dielectric surface passivation technologies in III-nitride (III-N) insulated-gate power switching transistors for enhanced stability and dynamic performance. In III-N metal-insulator-semiconductor high-electron-mobility transistors (MIS-HEMTs) that feature a buried channel, the polarized barrier layer separates the critical dielectric/III-N interface from the two-dimensional electron gas (2DEG) channel and consequently complicates interface trap analysis. The barrier layer not only causes underestimation/uncertainty in interface trap extraction using conventional ac-conductance method but also allows the Fermi level dipping deep into the bandgap at the pinch-off of the 2DEG channel. To address these issues, we analyze the frequency/temperature dispersions of the second slope in capacitance-voltage characteristics and develop systematic ac-capacitance techniques to realize interface trap mapping in MIS-HEMTs. The correlation between ac-capacitance and pulse-mode hysteresis measurements show that appropriate gate bias need to be selected in the interface trap characterization of MIS-HEMTs, in order to match the time constant of interface traps at the Fermi level with ac frequency and pulsewidth. [ABSTRACT FROM AUTHOR]

Published

2015

22. A GaN Pulse Width Modulation Integrated Circuit for GaN Power Converters.

Author

Wang, Hanxing, Kwan, Alex Man Ho, Jiang, Qimeng, and Chen, Kevin J.

Subjects

GALLIUM nitride, INTEGRATED circuits, MICROELECTRONICS, REDUCED instruction set computers, INFORMATION technology

Abstract

We report the first gallium nitride (GaN)-based pulse width modulation (PWM) integrated circuit (IC) featuring monolithically integrated enhancement- and depletion-mode high electron mobility transistors and lateral field-effect rectifiers on the GaN smart power technology platform. The PWM IC is able to generate 1-MHz PWM signal with its duty cycle modulated effectively by a reference voltage ( Vc) over a wide range with good linearity. It features a 5 V supply voltage and is composed of a sawtooth generator and a comparator, both of which can be operated at 1 MHz and exhibit proper functionality over a wide temperature range (from 25 °C to 250 °C). This circuit demonstration further proves the feasibility of an all-GaN solution that features monolithically integrated peripheral gate control circuits and power switches for GaN power converters. An all-GaN solution would lead to a compact system with improved efficiency and enhanced reliability. [ABSTRACT FROM AUTHOR]

Published

2015

23. Normally off Al2O3–AlGaN/GaN MIS-HEMT With Transparent Gate Electrode for Gate Degradation Investigation.

Author

Lu, Yunyou, Li, Baikui, Tang, Xi, Jiang, Qimeng, Yang, Shu, Tang, Zhikai, and Chen, Kevin J.

Subjects

ELECTRIC properties of aluminum oxide, ELECTRIC properties of aluminum gallium nitride, HIGH electron mobility transistor circuits, ELECTROLUMINESCENCE, MODULATION-doped field-effect transistors, METAL-insulator-semiconductor devices, MICROFABRICATION

Abstract

Al2O3–AlGaN/GaN metal–insulator–semiconductor high-electron-mobility transistors (MIS-HEMTs) featuring indium tin oxide transparent gate electrode are fabricated for the purpose of evaluating the gate reliability. The transparent gate electrode allows electroluminescence (EL) observation in the region directly under the gate, which cannot be performed in conventional MIS-HEMTs with opaque gate electrode. Normally OFF transparent-gate MIS-HEMTs were realized by implanting fluorine ions into the AlGaN barrier prior to the deposition of Al2O3. The dependence of EL on bias condition was investigated with the color of EL resolved by filters. Gate dielectric degradation in MIS-HEMTs was induced by OFF state drain-bias stress, as detected by the increased gate leakage current. Location of the gate degradation could be clearly identified by EL imaging through the transparent gate. From the EL image, the passivation layer under the overhang of T-shaped gate is found to be vulnerable to OFF-state stress, which is confirmed by simulation. [ABSTRACT FROM AUTHOR]

Published

2015

24. Influence of AlN Passivation on Dynamic ON-Resistance and Electric Field Distribution in High-Voltage AlGaN/GaN-on-Si HEMTs.

Author

Tang, Zhikai, Huang, Sen, Tang, Xi, Li, Baikui, and Chen, Kevin J.

Subjects

ELECTRIC resistance, ELECTRIC fields, ELECTRIC potential, ELECTROLUMINESCENCE, MODULATION-doped field-effect transistors

Abstract

We investigate in detail the influence of AlN passivation on dynamic ON-resistance ( \(R_{\mathrm{{\scriptstyle ON}}}\) ) and electric field ( \(E\) -field) distribution in high-voltage AlGaN/GaN high electron mobility transistors (HEMTs) on a Si substrate based on pulsed \(I\) – \(V\) measurements, electroluminescence (EL) microscopy, and 2-D physics-based numerical device simulations. It is found that the dynamic \(R_{\mathrm{{\scriptstyle ON}}}\) increase has been significantly suppressed to below 10% at various temperatures ranging from −50 to 200 °C owing to the effective and robust compensation of deep acceptor-like trap states at the AlN/GaN (passivation/cap) interface by the additional positive polarization charges induced in the epitaxial AlN thin passivation layer grown in a plasma-enhanced atomic layer deposition system. To the best of our knowledge, this is the first time that highly suppressed current collapse in an AlGaN/GaN HEMT on a Si substrate within a wide temperature range is ever reported. By monitoring the dynamic \(R_{\mathrm{{\scriptstyle ON}}}\) for 100 consecutive 133-kHz switching cycles, its variation is observed to be less than 2.5%, indicating excellent stability of the passivation effectiveness. The electric field in an AlN-passivated device is found to be well confined at the drain-side gate edge, as shown in EL measurement and numerical simulation results. This phenomenon directly suggests that the virtual gate effect arising from surface trap charging has been effectively alleviated by the AlN passivation technique. [ABSTRACT FROM AUTHOR]

Published

2014

25. A Highly Linear Integrated Temperature Sensor on a GaN Smart Power IC Platform.

Author

Kwan, Alex Man Ho, Guan, Yue, Liu, Xiaosen, and Chen, Kevin J.

Subjects

ANALOG integrated circuits, TEMPERATURE sensors, SMART power grids, INTEGRATED circuits, ELECTRIC potential, SCHOTTKY barrier diodes

Abstract

On a GaN smart power integrated circuit (IC) platform, a highly linear (i.e., proportional to absolute temperature) temperature sensor IC is demonstrated for building voltage references as well as temperature compensation functional blocks. The circuit is designed based on the temperature-dependent characteristics of GaN-based peripheral devices (e.g., heterojunction Schottky barrier diode, enhancement-/depletion-mode high electron mobility transistors, and lateral field-effect rectifiers) that are monolithically integrated with high-voltage power devices. This monolithic integration scheme facilitates the design efforts in taking full advantages of GaN’s superior capability to operate at high temperatures. Proper circuit operation was demonstrated at 275 °C. [ABSTRACT FROM AUTHOR]

Published

2014

26. 900 V/1.6 m\Omega\cdotcm^2 Normally Off Al2O3/GaN MOSFET on Silicon Substrate.

Author

Wang, Maojun, Wang, Ye, Zhang, Chuan, Xie, Bing, Wen, Cheng P., Wang, Jinyan, Hao, Yilong, Wu, Wengang, Chen, Kevin J., and Shen, Bo

Subjects

METAL oxide semiconductor field-effect transistors, SILICON wafers, PERFORMANCE of electronics, ALUMINUM oxide, LOGIC circuits, BREAKDOWN voltage

Abstract

In this paper, we report the device performance of a high-voltage normally off Al2O3/GaN MOSFET on the Si substrate. Normally off operation is obtained by multiple cycles of O2 plasma oxidation and wet oxide-removal gate recess process. The recessed normally off GaN MOSFET with 3 \mum gate-drain distance exhibits a maximum drain current of 585 mA/mm at 9 V gate bias. The threshold voltage of the MOSFET is 2.8 V with a standard derivation of 0.2 V on the sample with an area of 2 \,\times\, 2 {\rm cm}^{2} . The gate leakage current is below 10^{-6}~{\rm mA}/{\rm mm} during the whole gate swing up to 9 V and the I{\scriptstyleON}/I{\scriptstyle OFF} ratio is larger than 10^{9} , indicating the good quality of Al2O3 gate insulator. The MOSFET with 10 \mum gate-drain distance shows a three terminal OFF-state breakdown voltage (BV) of 967 V at zero gate-source bias with a drain leakage current criterion of 1 \muA/mm . The specific ON-resistance $(R_{{{\scriptstyle {\rm ON}}},{\rm SP}}) of the device is 1.6 m\Omega\,\cdot\,cm^2 and the power figure of merit (BV^2/R{{\scriptstyle ON},SP}) is 584 MW/cm^2 . [ABSTRACT FROM AUTHOR]

Published

2014

27. A High-Voltage Low-Standby-Power Startup Circuit Using Monolithically Integrated E/D-Mode AlGaN/GaN MIS-HEMTs.

Author

Jiang, Qimeng, Tang, Zhikai, Liu, Cheng, Lu, Yunyou, and Chen, Kevin J.

Subjects

SWITCHING power supplies, SEMICONDUCTOR devices, LOGIC circuits, ALUMINUM gallium nitride, THRESHOLD voltage

Abstract

We experimentally demonstrate a high-voltage low-standby power startup circuit for powering up the off-line switched-mode power supply (SMPS) during the startup period by exploiting monolithically integrated enhancement/depletion-mode metal–insulator–semiconductor high electron mobility transistors (E/D-mode MIS-HEMTs) fabricated on a GaN-on-Si power device platform. The E/D-mode MIS-HEMTs exhibit a threshold voltage of +1.2 and -11~V, respectively. The high-voltage D-mode device used in the demonstration features an OFF-state breakdown voltage of 640 V and a safe operating area with a thermal limitation of 11.6 W/mm, whereas the low-voltage E-mode device features a source-gate breakdown voltage of 98 V, satisfying the requirement of the startup circuit. The functionality of the startup circuit is successfully achieved with an input voltage range 10–200 V and a startup current of 1.08 mA. [ABSTRACT FROM AUTHOR]

Published

2014

28. Analytical Modeling of Capacitances for GaN HEMTs, Including Parasitic Components.

Author

Zhang, Aixi, Zhang, Lining, Tang, Zhikai, Cheng, Xiaoxu, Wang, Yan, Chen, Kevin J., and Chan, Mansun

Subjects

ELECTRIC capacity, CAPACITORS, LOGIC circuits, INTEGRATED circuits, HIGH electron mobility transistor circuits, SURFACE potential, MOS integrated circuits

Abstract

In this paper, a surface potential-based terminal charge and capacitance model, including parasitic components for AlGaN/GaN HEMTs is developed. First, by solving the charge control equations, the sheet charge density in the channel is modeled with a close-form expression. Then, using this result, based on the surface potential definition, the intrinsic terminal charges and capacitances are derived consistently with current model. Finally, by introducing parasitic components, the capacitances for the full structure of the HEMT devices are given. The model is evaluated step-by-step with good agreements compared with the TCAD simulations and the experimental data. Meanwhile, the effects of bulk traps and surface traps in the capacitances are analyzed. The complete model, including currents and capacitances has been implemented in i-MOS platform for evaluations and circuit simulations. [ABSTRACT FROM PUBLISHER]

Published

2014

29. Guest Editorial Special Issue on GaN Electronic Devices.

Author

Ghione, Giovanni, Chen, Kevin J., Egawa, Takashi, Meneghesso, Gaudenzio, Palacios, Tomas, and Quay, Ruediger

Subjects

*ELECTRONICS, *COMPUTER simulation, *SEMICONDUCTOR characterization, *DIGITAL Object Identifiers, *ELECTRONIC amplifiers, *ELECTRIC resistors

Abstract

Due to the rapid advances taking place in the development and application of GaN electronics, there is an immediate need to take cognizance of the recent technological improvements and bring the potential and opportunities that exist in the area to a wider device community. The primary goal of this special issue is, therefore, to put together works in different aspects, including modeling, design, technology, characterization and applications so that this special issue will not only be of great archival value but also attract new researchers into this area for Digital Object Identifier 10.1109/TED.2013.2278653 further accelerating the application of III-N devices in building reliable, cheaper, and high-performance electronic systems. The papers collected in this special issue have been grouped into six topics. They are: 1) Fabrication and characterization of GaN-based devices. 2) High power GaN HEMTs for power switching applications. 3) High speed GaN HEMTs for RF applications. 4) Reliability and parasitic issues in GaN HEMTs. 5) Simulation-based development of GaN HEMTs devices. 6) GaN-based low noise amplifiers and gate drive circuits. [ABSTRACT FROM AUTHOR]

Published

2013

30. Fabrication and Characterization of Enhancement-Mode High-\kappa~LaLuO3-AlGaN/GaN MIS-HEMTs.

Author

Yang, Shu, Huang, Sen, Schnee, Michael, Zhao, Qing-Tai, Schubert, Jrgen, and Chen, Kevin J.

Subjects

ALUMINUM gallium nitride, MODULATION-doped field-effect transistors, GALLIUM nitride, LOGIC circuits, THRESHOLD voltage, ELECTRODES

Abstract

In this paper, we investigate the enhancement-mode (E-mode) LaLuO3 (LLO)-AlGaN/GaN metal-insulator-semiconductor high-electron mobility transistors (MIS-HEMTs) fabricated using fluorine (F) plasma ion implantation with a gate-dielectric-first planar process. The E-mode MIS-HEMTs exhibit a threshold voltage (VTH) of 0.6 V, a peak transconductance of \sim193~mS/mm, a small hysteresis of 0.04 V in linear region characterized by a pulse-mode current-voltage measurement, and significantly suppressed current collapse under high-drain-bias switching conditions. X-ray photoelectron spectroscopy and secondary ion mass spectrometry analyses manifest that the negatively charged F ions penetrating into the (Al)GaN barrier layer serve as the primary VTH modulation mechanism, whereas the F ions in the fluorinated LLO film form chemical bonds with La/Lu atoms and become charge-neutral. The suppressed current collapse is verified as an advantageous byproduct of the F plasma ion implantation that also fluorinated the SiNx sidewalls in the vicinity of the gate electrode, and therefore, suppress electron injection to the gate-drain access region. [ABSTRACT FROM AUTHOR]

Published

2013

31. Schottky-Contact Technology in InAlN/GaN HEMTs for Breakdown Voltage Improvement.

Author

Zhou, Qi, Chen, Wanjun, Liu, Shenghou, Zhang, Bo, Feng, Zhihong, Cai, Shujun, and Chen, Kevin J.

Subjects

BREAKDOWN voltage, ELECTRIC breakdown, ELECTRIC conductivity, SCHOTTKY barrier, SEMICONDUCTOR-metal boundaries, METALLIZING

Abstract

In this paper, we demonstrate a 253% improvement in the off-state breakdown voltage (BV) of the lattice-matched \In0.17\Al0.83 \N/GaN high-electron-mobility transistors (HEMTs) by using a new Schottky-contact technology. Based on this concept, the Schottky-source/drain and Schottky-source (SS) InAlN/GaN HEMTs are proposed. The proposed InAlN/GaN HEMTs with an LGD of 15 \mu\m showed a three-terminal BV of more than 600 V, while the conventional InAlN/GaN HEMTs of the same geometry showed a maximum BV of 184 V. Without using any field plate, the BV of 650 V was measured in the SS InAlN/GaN HEMTs with LGD = \15\ \mu\m, which is the highest BV ever achieved on InAlN/GaN HEMT. The corresponding specific on-resistance (Rsp, on) is as low as 3.4 \m\Omega \cdot \cm^2. A BV of 118 V was also obtained in SS InAlN/GaN HEMTs with LGD = \1\ \mu\m, which is the highest BV in GaN-based HEMTs featuring such a short LGD with GaN buffer. The improvement of the BV relies on the effective suppression of source carrier injection into the GaN buffer under the SS due to the smooth metal morphology and elimination of metal spikes in the Schottky metallization. [ABSTRACT FROM AUTHOR]

Published

2013

32. Improvement of the Off-State Breakdown Voltage With Fluorine Ion Implantation in AlGaN/GaN HEMTs.

Author

Wang, Maojun and Chen, Kevin J.

Subjects

*BREAKDOWN voltage, *FLUORINE, *ION implantation, *GALLIUM nitride, *FIELD-effect transistors, *ALUMINUM nitride

Abstract

Improvement of the AlGaN/GaN high-electron mobility transistor's (HEMT's) off -state breakdown voltage is achieved by implanting ^19\F^+ ions at an energy of 50 keV and dose of \1 \times \10^12\ \cm^-2 under the gate region using \BF3 as the source. The charge state of the implanted fluorine ions changes from positive to negative in the AlGaN/GaN structure because of fluorine's strong electronegativity. The negative-charged fluorine ions at the back side of the two-dimensional electron gas can raise the energy barrier of the GaN buffer layer under the channel, effectively blocking the current injected from the source to the high-field region of the GaN channel when the HEMT is biased at off-state. The source-injected electrons, if not blocked, could flow to the high-field region and initiate a premature three-terminal off-state breakdown in a conventional AlGaN/GaN HEMT. A 38% improvement of the three-terminal off-state breakdown voltage and 40% improvement of the power figure-of-merit VBD-off^2/Ron are achieved in the enhanced back barrier HEMT. [ABSTRACT FROM AUTHOR]

Published

2011

33. Characterization and Analysis of the Temperature-Dependent ON-Resistance in AIGaN/GaN Lateral Field-Effect Rectifiers.

Author

King-Yuen Wong, Wanjun Chen, and Chen, Kevin J.

Subjects

FREE electron theory of metals, ELECTRON mobility, PARTICLES (Nuclear physics), ELECTRONICS, SEMICONDUCTORS

Abstract

The ON-resistance and its temperature dependence of the high electron mobility transistor (HEMT)-compatible lateral field-effect rectifier (L-FER) are investigated. Three types of transfer length method (TLM) patterns are utilized to extract the temperature-dependent electrical parameters of the resistance model. The technique presented in this paper delivers a direct and simple methodology for the investigation of the temperature dependence of the ON-resistance in the L-FER. The simulated output characteristics of the L-FER are in good agreement with the experimental results. [ABSTRACT FROM AUTHOR]

Published

2010

34. Off-State Breakdown Characterization in AlGaN/GaN HEMT Using Drain Injection Technique.

Author

Maojun Wang and Chen, Kevin J.

Subjects

*GALLIUM nitride, *TRANSISTORS, *ELECTRIC currents, *IONIZATION (Atomic physics), *ELECTRIC breakdown

Abstract

AlGaN/GaN high-electron mobility transistor's (HEMT's) off-state breakdown is investigated using drain-current injection techniques with different injection current levels. Competitions between the source leakage and gate leakage, pure leakage and impact ionization, and source- and gate-injection-induced impact ionization during the drain-injection measurement are discussed in detail. It was found that the breakdown originates from the source/gate leakage at low drain injection levels but is dominated by source/gate-induced impact ionization process at high drain injection currents. The source-induced impact ionization usually precedes the gate-induced impact ionization in low-gate leakage devices, resulting in a premature three-terminal off-state breakdown. We also found that the gate-bias value affects the breakdown voltage in the conventional three-terminal off-state breakdown I-V measurement and should be carefully considered. [ABSTRACT FROM AUTHOR]

Published

2010

35. Integrated Voltage Reference Generator for GaN Smart Power Chip Technology.

Author

King-Yuen Wong, Wanjun Chen, and Chen, Kevin J.

Subjects

VOLTAGE references, SMART cards, INTEGRATED circuits, ELECTRONIC circuits, ELECTRIC generators

Abstract

GaN smart power chip technology has been realized using a GaN-on-Si HEMT platform, featuring monolithically integrated high-voltage power devices and low-voltage peripheral devices for mixed-signal functional blocks. In particular, this brief presents the imperative analog functional block-voltage reference generator for smart power applications with wide-temperature-range stability. The circuit is capable of proper functions within a wide temperature range from room temperature up to 250 °C, illustrating the unique advantage of the wide-bandgap GaN in high-temperature operation. The voltage reference generator was designed with an AlGaN/GaN HEMT and Schottky diodes, and the devices were operated in the subthreshold regime to obtain low power consumption. The voltage reference generator achieved an average drift of less than 0.5 mV/°C and can be used as a reference voltage in various biasing and sensing circuits. [ABSTRACT FROM AUTHOR]

Published

2010

36. Zero-Bias Mixer Based on A1GaN/GaN Lateral Field-Effect Diodes for High-Temperature Wireless Sensor and RFID Applications.

Author

King-Yuen Wong, Wanjun Chen, Qi Zhou, and Chen, Kevin J.

Subjects

MIXING circuits, SEMICONDUCTOR diodes, GALLIUM nitride, ELECTRON mobility, SEMICONDUCTOR wafers, HIGH temperatures, WIRELESS sensor networks, RADIO frequency identification systems

Abstract

In this paper, a zero-bias mixer using a lateral field-effect diode fabricated on standard GaN-on-Si AlGaN/GaN high electron-mobility-transistor wafers is demonstrated. The diode features strong nonlinearity near zero bias, enabled by a threshold-voltage modulation using a fluorine-plasma-treatment technique. The maximum change in conductance was adjusted to ~0 V, leading to optimal conversion loss (CL) of the mixer at zero bias and eliminating the need for any dc supplies. The mixer is characterized from room temperature (RT) to 250 °C. At 2.5 GHz and at RT, the CL and third-order intermodulation intercept point are 12.9 dB and 17.64 dBm, respectively. The operation of the proposed diode is modeled by a physical equivalent circuit, wit the element values extracted from the measured S-parameters. The voltage-biasing dependence of the CL can be explained by a the model. The high-temperature operation of the mixer shows that the proposed mixer can perform well in high-temperature and ultralow-power applications. [ABSTRACT FROM AUTHOR]

Published

2009

37. DC and RF Characteristics of A1GaN/GaN/InGaN/GaN Double-Heterojunction HEMTs.

Author

Jie Liu, Yugang Zhou, Jia Zhu, Yong Cai, Kei May Lau, and Chen, Kevin J.

Subjects

RADIO frequency, HETEROJUNCTIONS, MODULATION-doped field-effect transistors, PIEZOELECTRIC semiconductors, TRANSMISSION electron microscopy, ATOMIC force microscopy

Abstract

We present the detailed dc and radio-frequency characteristics of an Al0.3Ga0.7N/GaN/In0.1Ga0.9N/GaN double-heterojunction HEMT (DH-HEMT) structure. This structure incorporates a thin (3 nm) In0.1Ga0.9N notch layer inserted at a location that is 6-nm away from the AlGaN/GaN heterointerface. The In0.1Ga0.9N layer provides a unique piezoelectric polarization field which results in a higher potential barrier at the backside of the two-dimensional electron gas channel, effectively improving the carrier confinement and then reducing the buffer leakage. Both depletion-mode (D-mode) and enhancement-mode (E-mode) devices were fabricated on this new structure. Compared with the baseline AlGaN/GaN HEMTs, the DH-HEMT shows lower drain leakage current. The gate leakage current is also found to be reduced, owing to an improved surface morphology in InGaN-incorporated epitaxial structures. DC and small- and large-signal microwave characteristics, together with the linearity performances, have been investigated. The channel transit delay time analysis also revealed that there was a minor channel in the InGaN layer in which the electrons exhibited a mobility slightly lower than the GaN channel. The E-mode DH-HEMTs were also fabricated using our recently developed CF4-based plasma treatment technique. The large-signal operation of the E-mode GaN-based HEMTs was reported for the first time. At 2 GHz, a 1 × 100 μm E-mode device demonstrated a maximum output power of 3.12 W/mm and a power-added efficiency of 49% with single-polarity biases (a gate bias of +0.5 V and a drain bias of 35 V). An output third-order interception point of 34.7 dBm was obtained in the E-mode HEMTs. [ABSTRACT FROM AUTHOR]

Published

2007

38. A Physical Model for On-Chip Spiral Inductors With Accurate Substrate Modeling.

Author

Huo, X., Chan, Philip C. H., Chen, Kevin J., and Luong, Howard C.

Subjects

ON-chip charge pumps, ELECTRIC inductors, ELECTRIC inductance, RADIO frequency, DIELECTRIC films, EDDY currents (Electric)

Abstract

A physical-based analytical model for on-chip inductors is developed. A ladder structure is used to model the skin and proximity effects in metal lines. The substrate electric and substrate magnetic losses are accurately modeled by RC and RL ladder structures, respectively. The effective inductance reduction due to the eddy current in the lossy silicon substrate at high frequency is modeled by a negative mutual inductance between the inductor and the substrate. All the model parameters can be calculated from the layout and process parameters. On-chip inductors with different geometries and substrate resistivities were fabricated for the verifications. The measured results are in very good agreement with the proposed model. This generic model can be applied to various substrate resistivities; thus, it is suitable for different technologies. This model can facilitate the design and optimization of on-chip inductors for RF IC applications. [ABSTRACT FROM AUTHOR]

Published

2006

39. Monolithically Integrated Enhancement/Depletion-Mode A1GaN/GaN HEMT Inverters and Ring Oscillators Using CF4 Plasma Treatment.

Author

Yong Cai, Zhiqun Cheng, Wilson Chak Wah Tang, Kei May Lau, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, GALLIUM nitride, FIELD-effect transistors, ELECTRIC inverters, RAPID thermal processing, ELECTRONIC circuits

Abstract

Fabrication and characterization of AlGaN/GaN HEMT inverters and ring oscillators utilizing integrated enhancement/depletion-mode (E/D-mode) AlGaN/GaN HEMTs are presented. The core technique is a CF4 plasma treatment that can effectively convert a D-mode AlGaN/GaN heterostructure to an E-mode heterostructure. A significant advantage of the plasma-treated E-mode HEMTs is that the gate current is reduced in both reverse- and forward-bias regions due to the effectively enhanced barrier height induced by the negatively charged fluorine ions in the AlGaN barrier. As a result, the input voltage swing is expanded by about 1 V for the E-mode HEMT, enabling convenient input/output logic level matching for multistage logic circuits such as ring oscillators. The fabricated 17-stage direct-coupled field-effect transistor logic ring oscillator using the 1-μm-gate technology can operate properly at a larger supply voltage of 3.5 V, and a minimum propagation delay of 130 ps/stage is achieved. [ABSTRACT FROM AUTHOR]

Published

2006

40. Control of Threshold Voltage of A1GaN/GaN HEMTs by Fluoride-Based Plasma Treatment: From Depletion Mode to Enhancement Mode.

Author

Yong Cai, Yugang Zhou, Kei May Lau, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, ELECTRIC potential, THERMAL electromotive force, GALLIUM nitride, ALUMINUM nitride, RAPID thermal processing, ELECTRON gas

Abstract

This paper presents a method with an accurate control of threshold voltages (Vth) of AlGaN/GaN high-electron mobility transistors (HEMTs) using a fluoride-based plasma treatment. Using this method, the Vth of AlGaN/GaN HEMTs can be continuously shifted from 4 V in a conventional depletion-mode (D-mode) AlGaN/GaN HEMT to 0.9 V in an enhancement-mode AlGaN/GaN HEMT. It was found that the plasma-induced damages result in a mobility degradation of two-dimensional electron gas. The damages can be repaired and the mobility can be recovered by a post-gate annealing step at 400 °C. At the same time, the shift in Vth shows a good thermal stability and is not affected by the post-gate annealing. The enhancement-mode HEMTs show a performance (transconductance, cutoff frequencies) comparable to the D-mode HEMTs. Experimental results confirm that the threshold-voltage shift originates from the incorporation of F ions in the AlGaN barrier. In addition, the fluoride-based plasma treatment was also found to be effective in lowering the gate-leakage current, in both forward and reverse bias regions. A physical model of the threshold voltage is proposed to explain the effects of the fluoride-based plasma treatment on AlGaN/GaN HEMTs. [ABSTRACT FROM AUTHOR]

Published

2006

41. Enhancement-Mode AlGaN/GaN HEMTs on Silicon Substrate.

Author

Shuo Jia, Yong Cai, Wang, Deliang, Baoshun Zhang, Lau, Kei May, and Chen, Kevin J.

Subjects

SILICON, SEMICONDUCTORS, ELECTRIC conductivity, SEMICONDUCTOR wafers, ELECTRONICS

Abstract

High-performance enhancement-mode AIGaN/GaN HEMTs (E-HEMTs) were demonstrated with samples grown on a low-cost silicon substrate for the first time. The fabrication process is based on a fluoride-based plasma treatment of the gate region and postgate annealing at 450 °C. The fabricated E-HEMTs have nearly the same peak transconductance (Gm) and cutoff frequencies as the conventional depletion-mode HEMTs fabricated on the same wafer, suggesting little mobility degradation caused by the plasma treatment. [ABSTRACT FROM AUTHOR]

Published

2006