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1. Impacts of Backside Insulation on the Dynamic On-Resistance of Lateral p-GaN HEMTs-on-Si

Author

Wang, Yu-Xuan, Tai, Mao-Chou, Chang, Ting-Chang, Huang, Wei-Chen, Wan, Zeyu, Li, Simon, Sze, Simon, and Xia, Guangrui

Subjects
Physics - Applied Physics
Abstract

We examined the effect of backside insulation on the dynamic on-resistance of lateral p-GaN HEMTs. To gain a comprehensive understanding of the dynamic onresistance difference between substrate grounded and substrate floating p-GaN HEMTs, we conducted in-circuit double pulse testing and long-term direct current (DC) bias stress. We have realized that while backside insulation can enhance the breakdown voltage of lateral p-GaN HEMTs, it also comes with a tradeoff in device reliability. Results through Sentaurus TCAD simulation suggest that the use of backside insulation in devices gradually disperses potential to the buffer barrier. As a result, the potential barrier at the buffer edge of the 2DEG channel decreases significantly, leading to considerable electron trappings at buffer traps. This breakdown voltage and reliability tradeoff also applies to HEMT technologies using insulating substrates.

Published
2024

2. Significant Photoluminescence Improvements from Bulk Germanium-Based Thin Films with Ultra-low Threading Dislocation Densities

Author

Wang, Liming, Kassa, Gideon, Liu, Jifeng, and Xia, Guangrui

Subjects
Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

Our study focused on the Ge thickness and TDD impacts on Ge's photoluminescence (PL). The PL peak intensity of a bulk Ge sample (TDD = 6000 cm-2, n-doping = 1e16 cm-3) experiences a remarkable 32-fold increase as the thickness is reduced from 535 to 2 microns. This surpasses the PL peak intensity of a best-performing epitaxial-Ge on Si (epi-Ge) (0.75 micron thick, biaxial tensile strain= 0.2 percent, n-doping = 7e18 cm-3) by a factor of 2.5. Furthermore, the PL peak intensity of a 405-micron thick zero-TDD bulk Ge sample (n-doping = 5e17 cm-3) is 9.7 times that of the 0.75-micron thick epi-Ge, rising to 12.1 times when thinned to 1 micron. The bulk Ge-based TDD reduction approach can work in conjunction with n-type doping and strain engineering to enhance Ge laser performance, and relax the requirement on the latter two approaches.

Published
2024

3. Sub-10-micron thick Ge thin films from bulk-Ge substrates via a wet etching method

Author

Wang, Liming and Xia, Guangrui

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

Low-defect-density Ge thin films are critical in Ge based optical devices (optical detectors, LEDs and Lasers) integrated with Si electronic devices for low-cost, highly integrated photonic circuits. In this work, Ge thin films prepared by wet etching with four different solutions were studied in terms of the surface morphology, defect density and achievable thickness. Both nanostrip-based solution (1:1:10) and HCl-based solution (1:1:5) were able to wet-etch 535 micron thick bulk-Ge substrates to Ge films thinner than 10 micron within 53 hours. The corresponding RMS surface roughness was 32 nm for the nanostrip-based solution and 10 nm for the HCl-based solution. The good quality of bulk-Ge was preserved before and after the etching process according to the HRXRD results. The low threading dislocation density of 6000-7000 cm-2 was maintained in the process of wet etching without introducing extra defects. This approach provides an inexpensive and convenient way to prepare sub-10-micron thick Ge thin films, enabling future studies of low-defect-density Ge-based devices such as photodetectors, LEDs, and lasers.

Published
2022

4. Theoretical study of small signal modulation behavior of Fabry-Perot Germanium-on-Silicon lasers

Author

Zhu, Ying, Wang, Liming, Li, Zhiqiang, Wen, Ruitao, and Xia, Guangrui

Subjects
Physics - Optics, Condensed Matter - Materials Science
Abstract

This work investigated the small signal performance of Fabry-Perot Ge-on-Si lasers by modeling and simulations. The 3dB bandwidth dependence on the structure parameters such as poly-Si cladding thickness, Ge cavity width and thickness, and minority carrier lifetime were studied. A 3dB bandwidth of 33.94 GHz at a biasing current of 270.5 mA is predicted after Ge laser structure optimization with a defect limited carrier lifetime of 1 ns.

Published
2022
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5. Improved Gate Reliability of p-GaN Gate HEMTs by Gate Doping Engineering

Author

Zhou, Guangnan, Zeng, Fanming, Gao, Rongyu, Wang, Qing, Cheng, Kai, Xia, Guangrui, and Yu, Hongyu

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

We present a novel p-GaN gate HEMT structure with reduced hole concentration near the Schottky interface by doping engineering in MOCVD, which aims at lowering the electric field across the gate. By employing an additional unintentionally doped GaN layer, the gate leakage current is suppressed and the gate breakdown voltage is boosted from 10.6 to 14.6 V with negligible influence on the threshold voltage and on-resistance. Time-dependent gate breakdown measurements reveal that the maximum gate drive voltage increases from 6.2 to 10.6 V for a 10-year lifetime with a 1% gate failure rate. This method effectively expands the operating voltage margin of the p-GaN gate HEMTs without any other additional process steps.

Published
2021

6. Formation of Ultra-High-Resistance Au/Ti/p-GaN Junctions and the Applications in AlGaN/GaN HEMTs

Author

Zhou, Guangnan, Jiang, Yang, Yang, Gaiying, Wang, Qing, Fan, Mengya, Jiang, Lingli, Yu, Hongyu, and Xia, Guangrui

Subjects
Condensed Matter - Materials Science
Abstract

We report a dramatic current reduction, or a resistance increase, by a few orders of magnitude of two common-anode Au/Ti/pGaN Schottky junctions annealed within a certain annealing condition window (600 - 700 oC, 1 - 4 min). Results from similar common-anode Schottky junctions made of Au/p-GaN, Al/Ti/p-GaN and Au/Ti/graphene/p-GaN junctions demonstrated that all the three layers (Au, Ti and p-GaN) are essential for the increased resistance. Raman characterization of the p-GaN showed a decrease of the Mg-N bonding, i.e., the deactivation of Mg, which is consistent with the Hall measurement results. Moreover, this high-resistance junction structure was employed in p-GaN gate AlGaN/GaN HEMTs. It was shown to be an effective gate technology that was capable to boost the gate breakdown voltage from 9.9 V to 13.8 V with a negligible effect on the threshold voltage or the sub-threshold slope.

Published
2021
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7. The stability of exfoliated FeSe nanosheets during in-air device fabrication process

Author

Yang, Rui, Luo, Weijun, Chi, Shun, Bonn, Douglas, and Xia, Guangrui

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We studied the stability and superconductivity of FeSe nanosheets during an in-air device fabrication process. Methods were developed to improve the exfoliation yield and to maintain the superconductivity of FeSe. Raman spectroscopy, atomic force microscopy, optical microscopy and time-of-flight-secondary-ion-mass-spectroscopy measurements show that FeSe nanosheets decayed in air. Precipitation of Se particles and iron oxidation likely occurred during the decay process. Transport measurements revealed that the superconductivity of FeSe disappeared during a conventional electron beam lithography process. Shadow mask evaporation and transfer onto pre-defined electrodes methods were shown to be effective in maintaining the superconductivity after the in-air device fabrication process. These methods developed provide a way of making high quality FeSe nano-devices.

Published
2018
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8. Stress engineering with silicon nitride stressors for Ge-on-Si lasers

Author

Ke, Jiaxin, Chrostowski, Lukas, and Xia, Guangrui

Subjects
Physics - Optics
Abstract

Side and top silicon nitride stressors were proposed and shown to be effective ways to reduce the threshold current Ith and improve the wall-plug efficiency {\eta}wp of Ge-on-Si lasers. Side stressors only turned out to be a more efficient way to increase {\eta}wp than using top and side stressors together. With the side stressors only and geometry optimizations, a {\eta}wp of 30.5% and an Ith of 50 mA (Jth of 37 kA/cm2) can be achieved with the defect limited carrier lifetime of 1 nsec. With the defect limited carrier lifetime of 10 nsec, an Ith of 7.8 mA (Jth of 5.8 kA/cm2) and a wall-plug efficiency of 38.7% can be achieved. These are tremendous improvements from the case without any stressors. These results give strong support to the Ge-on-Si laser technology and provide an effective way to improve the Ge laser performance.

Published
2016

9. Study of Black Phosphorus Using Angle-Resolved Polarized Raman Spectroscopy with 442 nm Excitation

Author

Luo, Weijun, Song, Qian, Zhou, Guangnan, Tuschel, David, and Xia, Guangrui

Subjects
Condensed Matter - Materials Science
Abstract

We investigated 10 to 200 nm thick black phosphorus flakes on SiO2/Si and polyimide substrates by Angle-resolved Polarized Raman spectra (ARPRS) using 442 nm excitation wavelength. The results revealed that ARPRS with 442 nm excitation can provide unambiguous, convenient, non-destructive and fast determination of BP's crystallographic orientation. The substrate and thickness dependencies of Raman spectra and Raman tensor elements were studied. These dependencies were shown to be influenced by Raman excitation laser heating effect. By comparing with in-situ Raman measurements at elevated temperatures, we were able to quantify the laser-heating effect, which is significant and hard to avoid for Raman measurements of BP on polyimide substrates due to the poor thermal conductivity of the substrate. Thermal processing by substrate heating was shown to have a significant impact on BP on SiO2/Si substrate, but not for BP on polyimide due to smaller thermal expansion mismatch. Our results give important insights on Raman Spectroscopy characterizations of BP on different substrates., Comment: 45 pages, 300 figures

Published
2016

10. Monolithic Integration of AlGaAs Distributed Bragg Reflectors on Virtual Ge Substrates via Aspect Ratio Trapping

Author

Lin, Yiheng, Shi, Wei, Li, Jizhong, Chang, Ting-Chang, Park, Ji-Soo, Hydrick, Jennifer, Duan, Zigang, Greenberg, Mark, Fiorenza, James G., Chrostowski, Lukas, and Xia, Guangrui

Subjects
Condensed Matter - Materials Science
Abstract

High quality AlxGa1-xAs distributed Bragg reflectors (DBRs) were successfully monolithically grown on on-axis Si (100) substrates via a Ge layer formed by aspect ratio trapping (ART) technique. The GaAs/ART-Ge/Si-based DBRs have reflectivity spectra comparable to those grown on conventional bulk off-cut GaAs substrates and have smooth morphology, and good periodicity and uniformity. Anitphase domain formation is significantly reduced in GaAs on ART-Ge/Si substrates, and etch pit density of the GaAs base layer on the ART-Ge substrates ranges from 10^5 to 6 x 10^6 cm^(-2). These results paved the way for future VCSEL growth and fabrication on these ART-Ge substrates and also confirm that virtual Ge substrates via ART technique are effective Si platforms for optoelectronic integrated circuits.

Published
2016

11. On the Origins of Near-Surface Stresses in Silicon around Cu-filled and CNT-filled Through Silicon Vias

Author

Zhu, Ye, Ghosh, Kaushik, Li, Hong Yu, Lin, Yiheng, Tan, Chuan Seng, and Xia, Guangrui

Subjects
Condensed Matter - Materials Science
Abstract

Micro-Raman spectroscopy was employed to study the near-surface stress distributions and origins in Si around through silicon vias (TSVs) at both room temperature and elevated temperatures for Cu-filled and CNT-filled TSV samples. From the observations, we proved that the stresses near TSVs are mainly from two sources: 1) pre-existing stress before via filling, and 2) coefficients of thermal expansion (CTE) mismatch-induced stress. CTE-mismatch-induced stress is shown to dominate the compressive regime of the near-surface stress distribution around Cu-filled TSV structures, while pre-existing stress dominates the full range of the stress distribution in the CNT-filled TSV structures. Once the pre-existing stress is minimized, the total stress around CNT-filled TSVs can be minimized accordingly. Therefore, compared to Cu-filled TSVs, CNT-filled TSVs hold the potential to circumvent the hassle of stress-aware circuit layout and to solve the stress-related reliability issues.

Published
2016
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12. Design Considerations of Biaxially Tensile-Strained Germanium-on-Silicon Lasers

Author

Li, Xiyue, Li, Zhiqiang, Li, Simon, Chrostowski, Lukas, and Xia, Guangrui

Subjects
Physics - Optics
Abstract

Physical models of Ge energy band structure and material loss were implemented in LASTIP(TM), a 2D simulation tool for edge emitting laser diodes. The model calculation is able to match experimental data available. Important design parameters of a Fabry-Perot Ge laser, such as the cavity length, thickness, width, polycrystalline Si cladding layer thickness were studied and optimized. The laser structure optimizations alone were shown to reduce Ith by 22-fold and increase the differential efficiency by 11 times. The simulations also showed that improving the defect limited carrier lifetime is critical for achieving an efficient and low-threshold Ge laser. With the optimized structure design (300 micron for the cavity length, 0.4 micron for the cavity width, 0.3 micron for the cavity thickness, and 0.6 micron for the polycrystalline Si cladding layer thickness) and a defect limited carrier lifetime of 100 ns, a wall-plug efficiency of 14.6% at 1mW output is predicted, where Jth of 2.8 kA/cm2, Ith of 3.3 mA, I_1mA of 9 mA, and differential efficiency of 23.6% can also be achieved. These are tremendous improvements from the available experimental values at 280 kA/cm2, 756 mA, 837 mA and 1.9%, respectively., Comment: 12 pages, 9 figures

Published
2015
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23. Impact of ion implantation damage and thermal budget on mobility enhancement in strained-Si N-channel MOSFETs

Author

Xia, Guangrui, Lee, Minjoo L., Anjum, Dalaver H., Hull, Robert, Klymko, Nancy, Nayfeh, Hasan M., Fitzgerald, Eugene A., Li, Jian, Antoniadis, Dimitri A., and Hoyt, Judy L.

Subjects
Electron mobility -- Research, Metal oxide semiconductor field effect transistors -- Research, Metal oxide semiconductor field effect transistors -- Electric properties, Ion implantation -- Research, Business, Electronics, Electronics and electrical industries
Abstract

Study was conducted to investigate the impact of processing factors such as ion implantation and rapid thermal annealing on mobility enhancement in strained-Si n-channel metal-oxide-semiconductor field-effect transistors (n-MOSFETs). Electron mobility enhancement is presented to degrade considerably when the implant dose is above a certain critical dose for a given annealing condition.

Published
2004

28. Oxygen-based digital etching of AlGaN/GaN structures with AlN as etch-stop layers

Author

Wu, Jingyi, Lei, Siqi, Cheng, Wei-chih, Sokolovskij, Robert, Wang, Qing, Xia, Guangrui, Yu, Hongyu, Wu, Jingyi, Lei, Siqi, Cheng, Wei-chih, Sokolovskij, Robert, Wang, Qing, Xia, Guangrui, and Yu, Hongyu

Abstract

O2 plasma-based digital etching of Al0.25Ga0.75N with a 0.8 nm AlN spacer on GaN was investigated using an inductively coupled plasma etcher. Silicon oxide layer was used as the hard mask. At 40 W RF bias power and 40 sccm oxygen flow, the etch depth of Al0.25Ga0.75N was 5.7 nm per cycle. The 0.8 nm AlN spacer layer acted as an etch-stop layer in three cycles. The surface roughness improved from 0.66 to 0.33 nm after the three and seven digital etch cycles. Compared to the dry etch only approach, this technique smoothed the surface instead of causing surface roughening. Compared to the selective thermal oxidation with a wet etch approach, this method is less demanding on the epitaxial growth and saves the oxidation process. It was shown to be effective in precisely controlling the AlGaN etch depth required for recessed-AlGaN HEMTs. © 2019 Author(s).

Published
2019

29. Oxygen-plasma-based digital etching for gan/algan high electron mobility transistors

Author

Wu, Jingyi, Jiang, Yang, Wan, Zeyu, Lei, Siqi, Cheng, Wei-chih, Zhou, Guangnan, Sokolovskij, Robert, Wang, Qing, Xia, Guangrui Maggie, Yu, Hongyu, Wu, Jingyi, Jiang, Yang, Wan, Zeyu, Lei, Siqi, Cheng, Wei-chih, Zhou, Guangnan, Sokolovskij, Robert, Wang, Qing, Xia, Guangrui Maggie, and Yu, Hongyu

Abstract

Digital etching is an effective method to lower dry etch damages in A1GaN/GaN HEMTs. This work systematically investigated O2-plasma-based digital etching of AlGaN and p-GaN. AlN layers were used as the etch stop layers in the AlGaN etch. Important process aspects such as the use of the AlN layers, the RF power, the oxygen flow rate, the oxidation time and the resulting roughness were studied. These are technically relevant to obtain controllable, uniform etch surfaces with low surface damages for better HEMT performance. © 2019 IEEE.

Published
2019

34. Investigation of mechanisms and influencing processing factors on mobility enhancement in strained Si n-MOSFETs

Author

Judy L. Hoyt., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., Xia, Guangrui, 1976, Judy L. Hoyt., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., and Xia, Guangrui, 1976

Abstract

Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2003., Includes bibliographical references (p. 92-95)., by Guangrui Xia., S.M.

Published
2014

35. Stress Engineering With Silicon Nitride Stressors for Ge-on-Si Lasers.

Author

Ke, Jiaxin, Chrostowski, Lukas, and Xia, Guangrui

Abstract

Side and top silicon nitride stressors were proposed and shown to be effective in reducing the threshold current $I_{{\rm{th}}}$ and in improving the wall-plug efficiency $\eta _{{\rm{wp}}} of Ge-on-Si lasers. Side stressors only turned out to be a more efficient way to increase \eta\mathbf{wp} than using the top and side stressors together. With the side stressors and geometry optimizations, a \eta\mathbf{wp} of 34.8% and an $I_{{\rm{th}}}$ of 36 mA ($J_{{\rm{th}}} of 27 kA/cm2) can be achieved with a defect limited carrier lifetime ( \tau p,n) of 1 ns. With \tau p,n = 10\ \;{\rm{ns}}, an $I_{{\rm{th}}}$ of 4 mA ( $J_{{\rm{th}}}$ of 3 kA/cm2) and a \eta_{\mathbf{wp}} of 43.8% can be achieved. These are tremendous improvements from the case with no stressors. These results give strong support to the Ge-on-Si laser technology and provide an effective way to improve the Ge laser performance. [ABSTRACT FROM PUBLISHER]

Published
2017
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36. Silicon-Germanium interdiffusion and its impacts on enhanced mobility MOSFETs

Author

Judy L. Hoyt., Massachusetts Institute of Technology. Dept. of Electrical Engineering and Computer Science., Xia, Guangrui, 1976, Judy L. Hoyt., Massachusetts Institute of Technology. Dept. of Electrical Engineering and Computer Science., and Xia, Guangrui, 1976

Abstract

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2006., This electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections., Includes bibliographical references (p. 180-188)., As complementary metal-oxide-semiconductor field-effect transistors (MOSFETs) scale, strained Si and SiGe technology have received more attention as a means of enhancing performance via improved carrier mobility. One of the biggest challenges for strained Si and SiGe technology is Si-Ge interdiffusion during thermal processing. Two different aspects of Si-Ge interdiffusion are explored in this work. The first part of this work demonstrates that Si-Ge interdiffusion and ion implantation damage during the fabrication of strained Si MOSFETs have significant impact on electron mobility and thus device performance. Long channel n-MOSFETs with different thermal processing and implant conditions were fabricated on both CZ Si wafers and strained Si/relaxed Sio.8Geo.2 heterostructures. In order to avoid scattering by ionized dopant impurities, neutral Si and Ge were implanted into the channel at six different doses ranging from 4 x 1012 cm-2 to 1 x 1015 atoms/cm2. It is shown that the mobility enhancement factor is degraded by RTA and ion implantation. For each RTA condition, there is a threshold implantation dose, above which the strained Si mobility starts to degrade significantly. The degradation is larger for devices with higher thermal budgets or implantation doses., (cont.) Si-Ge interdiffusion at the strained Si/relaxed Sio.sGeo.2 interface was found to be the major mobility degradation mechanism for devices with higher thermal budget, while for devices with lower thermal budget, residual ion implantation damage in the strained Si channel is considered to be the key degradation mechanism. Two-dimensional simulations are performed to generate as-implanted damage profiles of 30-nm scale MOSFETs. By comparing the 2D damage profiles with those generated by Si blanket implants, it is shown that 30-nm p-MOSFETs are more likely to suffer from mobility degradation than n-MOSFETs. The second part of this work, which is the main focus of this thesis, systematically investigated the Si-Ge interdiffusivity in epitaxial strained Si/SilyGey/strained Si/relaxed Silx.Gex and strained Si/relaxed SijlxGe, heterostructures for Ge fractions between 0 and 0.56 over the temperature range of 770 - 920 °C. Based on the interdiffusivity extracted from experiments, an analytic model was established for interdiffusion simulation. To the best of our knowledge, this work is the most complete study of Si-Ge interdiffusion and modeling to date. Boltzmann-Matano analysis was applied to extract interdiffusivity from the diffused Ge profiles of strained Si/relaxed SiljxoGexo heterostructures., (cont.) A model for the interdiffusivity suitable for use in the process simulator TSUPREM-4 was formulated. Si-Ge interdiffusivity was found to increase by 2.2X for every 10% increase in Ge fraction for interdiffusion under relaxed strain. Significantly enhanced Si-Ge interdiffusion was observed in SijlyGey layers under biaxial compressive strain. Si-Ge interdiffusivity was found to increase by 4.4X for every 0.42% increase in the magnitude of compressive strain, which is equivalent to 10% decrease in the substrate Ge fraction xo. These results were incorporated into an interdiffusion model that successfully predicts the interdiffusion of various SiGe heterostructures. Examples of the impact of interdiffusion on device design and process integration issues were given., by Guangrui Xia., Ph.D.

Published
2007

37. Monolithically integrated 940 nm VCSELs on bulk Ge substrates.

Author

Wan Z, Yang YC, Chen WH, Chiu CC, Zhao Y, Feifel M, Chrostowski L, Lackner D, Wu CH, and Xia G

Abstract

This research successfully developed an independent Ge-based VCSEL epitaxy and fabrication technology route, which set the stage for integrating AlGaAs-based semiconductor devices on bulk Ge substrates. This is the second successful Ge-based VCSEL technology reported worldwide and the first Ge-based VCSEL technology with key details disclosed, including Ge substrate specification, transition layer structure and composition, and fabrication process. Compared with the GaAs counterparts, after epitaxy optimization, the Ge-based VCSEL wafer has a 40% lower surface root-mean-square roughness and 72% lower average bow-warp. After device fabrication, the Ge-based VCSEL has a 10% lower threshold current density and 19% higher maximum optical differential efficiency than the GaAs-based VCSEL.

Published
2024
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