Control of ion content and nitrogen species using a mixed chemistry plasma for GaN grown at extremely high growth rates >9 μ m/h by plasma-assisted molecular beam epitaxy

Utilizing a modified nitrogen plasma source, plasma assisted molecular beam epitaxy (PAMBE) has been used to achieve higher growth rates in GaN. A higher conductance aperture plate, combined with higher nitrogen flow and added pumping capacity, resulted in dramatically increased growth rates up to 8...

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Veröffentlicht in:	Journal of applied physics 2015-10, Vol.118 (15)
Hauptverfasser:	Gunning, Brendan P., Clinton, Evan A., Merola, Joseph J., Doolittle, W. Alan, Bresnahan, Rich C.
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied physics Argon Dilution Epitaxial growth Gallium nitrides Germanium Growth rate Ion currents Molecular beam epitaxy Morphology Nitrogen Nitrogen plasma Organic chemistry Plasma Resistance Silicon Vapor pressure
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creator	Gunning, Brendan P. Clinton, Evan A. Merola, Joseph J. Doolittle, W. Alan Bresnahan, Rich C.
description	Utilizing a modified nitrogen plasma source, plasma assisted molecular beam epitaxy (PAMBE) has been used to achieve higher growth rates in GaN. A higher conductance aperture plate, combined with higher nitrogen flow and added pumping capacity, resulted in dramatically increased growth rates up to 8.4 μm/h using 34 sccm of N2 while still maintaining acceptably low operating pressure. It was further discovered that argon could be added to the plasma gas to enhance growth rates up to 9.8 μm/h, which was achieved using 20 sccm of N2 and 7.7 sccm Ar flows at 600 W radio frequency power, for which the standard deviation of thickness was just 2% over a full 2 in. diameter wafer. A remote Langmuir style probe employing the flux gauge was used to indirectly measure the relative ion content in the plasma. The use of argon dilution at low plasma pressures resulted in a dramatic reduction of the plasma ion current by more than half, while high plasma pressures suppressed ion content regardless of plasma gas chemistry. Moreover, different trends are apparent for the molecular and atomic nitrogen species generated by varying pressure and nitrogen composition in the plasma. Argon dilution resulted in nearly an order of magnitude achievable growth rate range from 1 μm/h to nearly 10 μm/h. Even for films grown at more than 6 μm/h, the surface morphology remained smooth showing clear atomic steps with root mean square roughness less than 1 nm. Due to the low vapor pressure of Si, Ge was explored as an alternative n-type dopant for high growth rate applications. Electron concentrations from 2.2 × 1016 to 3.8 × 1019 cm−3 were achieved in GaN using Ge doping, and unintentionally doped GaN films exhibited low background electron concentrations of just 1–2 × 1015 cm−3. The highest growth rates resulted in macroscopic surface features due to Ga cell spitting, which is an engineering challenge still to be addressed. Nonetheless, the dramatically enhanced growth rates demonstrate great promise for the future of III-nitride devices grown by PAMBE.
doi_str_mv	10.1063/1.4933278
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Alan ; Bresnahan, Rich C.</creator><creatorcontrib>Gunning, Brendan P. ; Clinton, Evan A. ; Merola, Joseph J. ; Doolittle, W. Alan ; Bresnahan, Rich C.</creatorcontrib><description>Utilizing a modified nitrogen plasma source, plasma assisted molecular beam epitaxy (PAMBE) has been used to achieve higher growth rates in GaN. A higher conductance aperture plate, combined with higher nitrogen flow and added pumping capacity, resulted in dramatically increased growth rates up to 8.4 μm/h using 34 sccm of N2 while still maintaining acceptably low operating pressure. It was further discovered that argon could be added to the plasma gas to enhance growth rates up to 9.8 μm/h, which was achieved using 20 sccm of N2 and 7.7 sccm Ar flows at 600 W radio frequency power, for which the standard deviation of thickness was just 2% over a full 2 in. diameter wafer. A remote Langmuir style probe employing the flux gauge was used to indirectly measure the relative ion content in the plasma. The use of argon dilution at low plasma pressures resulted in a dramatic reduction of the plasma ion current by more than half, while high plasma pressures suppressed ion content regardless of plasma gas chemistry. Moreover, different trends are apparent for the molecular and atomic nitrogen species generated by varying pressure and nitrogen composition in the plasma. Argon dilution resulted in nearly an order of magnitude achievable growth rate range from 1 μm/h to nearly 10 μm/h. Even for films grown at more than 6 μm/h, the surface morphology remained smooth showing clear atomic steps with root mean square roughness less than 1 nm. Due to the low vapor pressure of Si, Ge was explored as an alternative n-type dopant for high growth rate applications. Electron concentrations from 2.2 × 1016 to 3.8 × 1019 cm−3 were achieved in GaN using Ge doping, and unintentionally doped GaN films exhibited low background electron concentrations of just 1–2 × 1015 cm−3. 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Alan</creatorcontrib><creatorcontrib>Bresnahan, Rich C.</creatorcontrib><title>Control of ion content and nitrogen species using a mixed chemistry plasma for GaN grown at extremely high growth rates >9 μ m/h by plasma-assisted molecular beam epitaxy</title><title>Journal of applied physics</title><description>Utilizing a modified nitrogen plasma source, plasma assisted molecular beam epitaxy (PAMBE) has been used to achieve higher growth rates in GaN. A higher conductance aperture plate, combined with higher nitrogen flow and added pumping capacity, resulted in dramatically increased growth rates up to 8.4 μm/h using 34 sccm of N2 while still maintaining acceptably low operating pressure. It was further discovered that argon could be added to the plasma gas to enhance growth rates up to 9.8 μm/h, which was achieved using 20 sccm of N2 and 7.7 sccm Ar flows at 600 W radio frequency power, for which the standard deviation of thickness was just 2% over a full 2 in. diameter wafer. A remote Langmuir style probe employing the flux gauge was used to indirectly measure the relative ion content in the plasma. The use of argon dilution at low plasma pressures resulted in a dramatic reduction of the plasma ion current by more than half, while high plasma pressures suppressed ion content regardless of plasma gas chemistry. Moreover, different trends are apparent for the molecular and atomic nitrogen species generated by varying pressure and nitrogen composition in the plasma. Argon dilution resulted in nearly an order of magnitude achievable growth rate range from 1 μm/h to nearly 10 μm/h. Even for films grown at more than 6 μm/h, the surface morphology remained smooth showing clear atomic steps with root mean square roughness less than 1 nm. Due to the low vapor pressure of Si, Ge was explored as an alternative n-type dopant for high growth rate applications. Electron concentrations from 2.2 × 1016 to 3.8 × 1019 cm−3 were achieved in GaN using Ge doping, and unintentionally doped GaN films exhibited low background electron concentrations of just 1–2 × 1015 cm−3. The highest growth rates resulted in macroscopic surface features due to Ga cell spitting, which is an engineering challenge still to be addressed. 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Alan</creator><creator>Bresnahan, Rich C.</creator><general>American Institute of Physics</general><scope>AAYXX</scope><scope>CITATION</scope><scope>8FD</scope><scope>H8D</scope><scope>L7M</scope><scope>OTOTI</scope><orcidid>https://orcid.org/0000-0002-0497-5388</orcidid><orcidid>https://orcid.org/0000000204975388</orcidid></search><sort><creationdate>20151021</creationdate><title>Control of ion content and nitrogen species using a mixed chemistry plasma for GaN grown at extremely high growth rates >9 μ m/h by plasma-assisted molecular beam epitaxy</title><author>Gunning, Brendan P. ; Clinton, Evan A. ; Merola, Joseph J. ; Doolittle, W. 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Alan</au><au>Bresnahan, Rich C.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Control of ion content and nitrogen species using a mixed chemistry plasma for GaN grown at extremely high growth rates >9 μ m/h by plasma-assisted molecular beam epitaxy</atitle><jtitle>Journal of applied physics</jtitle><date>2015-10-21</date><risdate>2015</risdate><volume>118</volume><issue>15</issue><issn>0021-8979</issn><eissn>1089-7550</eissn><abstract>Utilizing a modified nitrogen plasma source, plasma assisted molecular beam epitaxy (PAMBE) has been used to achieve higher growth rates in GaN. A higher conductance aperture plate, combined with higher nitrogen flow and added pumping capacity, resulted in dramatically increased growth rates up to 8.4 μm/h using 34 sccm of N2 while still maintaining acceptably low operating pressure. 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subjects	Applied physics Argon Dilution Epitaxial growth Gallium nitrides Germanium Growth rate Ion currents Molecular beam epitaxy Morphology Nitrogen Nitrogen plasma Organic chemistry Plasma Resistance Silicon Vapor pressure
title	Control of ion content and nitrogen species using a mixed chemistry plasma for GaN grown at extremely high growth rates >9 μ m/h by plasma-assisted molecular beam epitaxy
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