10 results on '"Anderson, Travis"'
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2. Process Optimization for Selective Area Doping of GaN by Ion Implantation
- Author
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Ebrish, Mona A., Anderson, Travis J., Jacobs, Alan G., Gallagher, James C., Hite, Jennifer K., Mastro, Michael A., Feigelson, Boris N., Wang, Yekan, Liao, Michael, Goorsky, Mark, and Hobart, Karl D.
- Published
- 2021
- Full Text
- View/download PDF
3. Silicon Ion Implant Activation in β-(Al0.2Ga0.8)2O3.
- Author
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Jacobs, Alan G., Spencer, Joseph A., Tadjer, Marko J., Feigelson, Boris N., Lamb, Abbey, Lee, Ming-Hsun, Peterson, Rebecca L., Alema, Fikadu, Osinsky, Andrei, Zhang, Yuhao, Hobart, Karl D., and Anderson, Travis J.
- Subjects
CARRIER density ,SCHOTTKY barrier diodes ,SILICON ,GALLIUM alloys ,DOPING agents (Chemistry) ,GALLIUM - Abstract
As gallium oxide-based heterojunction devices gain prominence, low-resistance contacts to aluminum gallium oxide material are of increasing importance for high performance and access to modulation doped layers. Here, the activation of ion-implanted silicon donors is investigated as a function of donor density from 5 × 10
18 cm−3 to 1 × 1020 cm−3 , activation anneal duration from 6 s to 600 s, and activation temperature from 900°C to 1140°C. Importantly, ohmic behavior was achievable across a reasonably wide process window at moderate to high doping concentrations. Specific contact resistance of 1 × 10−3 Ω cm2 and sheet resistance of 2.8 kΩ/□ were achieved for a 60 nm-deep 1 × 1020 cm−3 box implant after activation at 1000°C for 6 s with standard Ti/Au contacts. Under these conditions, an activation efficiency of 7% was observed with Hall mobility of ~32 cm2 /Vs. Furthermore, we demonstrate a Schottky diode formed of implanted material with a rectification ratio > 106 and further confirm the Hall carrier density results using capacitance–voltage profiling analysis. Finally, we show the significant impact of anneal duration and the potential for deleterious over-annealing which reduces the active carrier density, mobility, and resultant material conductivity. [ABSTRACT FROM AUTHOR]- Published
- 2024
- Full Text
- View/download PDF
4. Novel Codoping Moiety to Achieve Enhanced P‐Type Doping in GaN by Ion Implantation.
- Author
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Jacobs, Alan G., Spencer, Joseph A., Hite, Jennifer K., Hobart, Karl D., Anderson, Travis J., and Feigelson, Boris N.
- Subjects
ION implantation ,RAPID thermal processing ,GALLIUM nitride ,MOIETIES (Chemistry) ,PHOTOTHERMAL effect ,NITROGEN - Abstract
Codoping of gallium nitride for improved acceptor ionization has long been theorized; however, reduction to practice proves difficult via growth. Herein, implementation of codoping via ion implantation and symmetric multicycle rapid thermal annealing utilizing magnesium codoped with silicon or oxygen is demonstrated. Results show enhanced photoluminescence with both donor species but with an order of magnitude greater increase with concurrent p‐type hall for codoping with oxygen. Furthermore, the addition of nitrogen to balance stoichiometry suppresses defect photoluminescence signals. The incorporation of the donor and nitrogen demonstrates defect reduction beyond magnesium, only implants despite the additional implant dose and resultant damage with coimplantation. The enhanced hole concentrations evident with oxygen incorporation reveal important considerations for device design given unintentional doping during growth and future incorporation of ion implantation capabilities. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
5. Efficient Activation and High Mobility of Ion-Implanted Silicon for Next-Generation GaN Devices.
- Author
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Jacobs, Alan G., Feigelson, Boris N., Spencer, Joseph A., Tadjer, Marko J., Hite, Jennifer K., Hobart, Karl D., and Anderson, Travis J.
- Subjects
RAPID thermal processing ,ION implantation ,GALLIUM nitride ,ION mobility ,SILICON ,HIGH voltages - Abstract
Selective area doping via ion implantation is crucial to the implementation of most modern devices and the provision of reasonable device design latitude for optimization. Herein, we report highly effective silicon ion implant activation in GaN via Symmetrical Multicycle Rapid Thermal Annealing (SMRTA) at peak temperatures of 1450 to 1530 °C, producing a mobility of up to 137 cm
2 /Vs at 300K with a 57% activation efficiency for a 300 nm thick 1 × 1019 cm−3 box implant profile. Doping activation efficiency and mobility improved alongside peak annealing temperature, while the deleterious degradation of the as-grown material electrical properties was only evident at the highest temperatures. This demonstrates efficient dopant activation while simultaneously maintaining low levels of unintentional doping and thus a high blocking voltage potential of the drift layers for high-voltage, high-power devices. Furthermore, efficient activation with high mobility has been achieved with GaN on sapphire, which is known for having relatively high defect densities but also for offering significant commercial potential due to the availability of cheap, large-area, and robust substrates for devices. [ABSTRACT FROM AUTHOR]- Published
- 2023
- Full Text
- View/download PDF
6. Role of Capping Material and GaN Polarity on Mg Ion Implantation Activation.
- Author
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Jacobs, Alan G., Feigelson, Boris N., Hite, Jennifer K., Gorsak, Cameron A., Luna, Lunet E., Anderson, Travis J., and Kub, Francis J.
- Subjects
ION implantation ,METAL organic chemical vapor deposition ,PLASMA-enhanced chemical vapor deposition ,SILICON nitride ,MAGNESIUM ,METAL activation ,ALUMINUM nitride - Abstract
Ion implantation of magnesium for p‐type GaN presents many opportunities; however, activation has proven difficult due to the decomposition of GaN at relevant annealing temperatures. Herein, testing the efficacy of multiple in situ and ex situ caps based on aluminum nitride and silicon nitride for GaN protection during annealing is presented. Photoluminescence shows better activation for in situ metal organic chemical vapor deposition (MOCVD)‐grown aluminum nitride caps compared with ex situ sputtered aluminum nitride and the best performance by ex situ plasma‐enhanced chemical vapor deposition (PECVD) silicon nitride. Furthermore, only samples annealed at the highest temperatures tested show preferential growth of UV luminescence to yellow‐green luminescence reinforcing the need for better capping solutions and higher temperature annealing. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
7. Reduced Contact Resistance in GaN Using Selective Area Si Ion Implantation.
- Author
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Gallagher, James C., Kub, Francis J., Anderson, Travis J., Koehler, Andrew D., Foster, Geoffrey M., Jacobs, Alan G., Feigelson, Boris N., Mastro, Michael A., Hite, Jennifer K., and Hobart, Karl D.
- Subjects
ION implantation ,RAPID thermal processing ,ELECTRIC lines - Abstract
We report selective area n-type doping using ion implantation of Si into semi-insulating, C-doped GaN samples activated using both conventional rapid thermal annealing (RTA) and 30 atm N2 overpressure annealing. Implanted regions were tested for Si activation using Circular Transmission Line Measurements (CTLM), while linear and circular photoconductive switches (PCSS) in the unimplanted regions were used as a test vehicle to separate implanted Si dopant activation from leakage paths generated by N vacancy formation due to damage and decomposition during annealing. We observed that at an optimal temperature around 1060 °C, a low contact resistivity of $1\times 10^{-6}\,\,\Omega $ -cm2 was obtained while preserving the breakdown of the unimplanted regions. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
8. Vertical GaN Junction Barrier Schottky Rectifiers by Selective Ion Implantation.
- Author
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Zhang, Yuhao, Liu, Zhihong, Tadjer, Marko J., Sun, Min, Piedra, Daniel, Hatem, Christopher, Anderson, Travis J., Luna, Lunet E., Nath, Anindya, Koehler, Andrew D., Okumura, Hironori, Hu, Jie, Zhang, Xu, Gao, Xiang, Feigelson, Boris N., Hobart, Karl D., and Palacios, Tomas
- Subjects
SCHOTTKY barrier diodes ,ION implantation ,ELECTRIC current rectifiers - Abstract
This letter demonstrates vertical GaN junction barrier Schottky (JBS) rectifiers fabricated with novel ion implantation techniques. We used two different methods to form the lateral p-n grids below the Schottky contact: 1) Mg implantation into n-GaN to form p-wells and 2) Si implantation into p-GaN to form n-wells. Specific differential ON-resistances ( R \mathrm{\scriptscriptstyle ON} ) of 1.5–2.5 \textm\Omega ~\cdot cm2 and 7–9 \textm\Omega ~\cdot cm2 were obtained in the Mg-implanted and Si-implanted JBS rectifiers, respectively. A breakdown voltage of 500–600 V was achieved in both devices, with a leakage current at high reverse biases at least 100-fold lower than conventional vertical GaN Schottky barrier diodes. The impact of n-well and p-well widths on the R \mathrm{\scriptscriptstyle ON} and BV was investigated. Fast switching capability was also demonstrated. This letter shows the feasibility of forming patterned p-n junctions by novel ion implantation techniques, to enable high-performance vertical GaN power devices. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
9. Improvements in the Annealing of Mg Ion Implanted GaN and Related Devices.
- Author
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Anderson, Travis J., Greenlee, Jordan D., Feigelson, Boris N., Hite, Jennifer K., Hobart, Karl D., and Kub, Francis J.
- Subjects
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ANNEALING of metals , *ION implantation , *MAGNESIUM ions , *GALLIUM nitride , *DOPING agents (Chemistry) , *PIN photodiodes - Abstract
The activation of ion implanted p-type dopants in GaN is notoriously difficult as the extremely high temperatures required to activate implanted Mg also damage the GaN crystal. In this paper, we present refinements to our novel annealing process (symmetric multicycle rapid thermal annealing) to reduce surface damage and contamination responsible for elevated leakage currents and non-ideal diode behavior. Furthermore, we apply the technique to Mg-implanted bulk GaN substrates to enable vertical power device structures, demonstrating rectifying p-i-n junctions. In addition, the technique was applied for edge termination in both p-i-n and Schottky barrier diodes, realizing floating guard ring and junction termination extension structures. The processes demonstrated here represents a key enabling step for future GaN-based power devices. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
10. Characterization of an Mg-implanted GaN p-i-n diode.
- Author
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Greenlee, Jordan D., Anderson, Travis J., Feigelson, Boris N., Hobart, Karl D., and Kub, Francis J.
- Subjects
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MAGNESIUM , *ION implantation , *GALLIUM nitride , *PIN diodes , *FABRICATION (Manufacturing) , *RAPID thermal processing , *SURFACE chemistry , *ATOMIC force microscopy - Abstract
An Mg-implanted p-i-n diode was fabricated and characterized. Mg activation was achieved using the multicycle rapid thermal annealing technique with rapid heating pulses up to 1340 °C. The surface of the implanted GaN after annealing was smooth (0.94 nm RMS roughness) with growth steps evident as characterized by atomic force microscopy. The full width at half-maximum of the implanted GaN E2 Raman mode approaches that of the as-grown GaN after the annealing process, indicating that the annealing process is able to reverse most of the implantation damage. The Mg-implanted p-i-n diode exhibits rectification and a low leakage current of 0.11 μA cm−2 at a bias of −10 V. Under forward bias, light emission was observed from the p-i-n diode. The implantation and activation of Mg in a GaN-based device, demonstrated for the first time in this research, is a key enabling step for future optoelectronic and power electronic devices. Current-voltage characteristics of the Mg-implanted p-i-n diode with an inset of the device schematic. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
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