Polarity Engineering in Nitride Heterostructures (Q84349): Difference between revisions

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(‎Removed claim: summary (P836): The project concentrates on nitro vertical forces with integrated design in Gas-post-crisis GaN substrate.It is the shoe features of the command unit of N-P tunnel juntions (TJ).Growth of N-P TJ prevaluing the active region of the destination RATHER that the active region.This results in an active region.Additally, suit will profit from keeping the n-type on the top.Will show that the botth of festivals can lead to new applications of light is...)
(‎Created claim: summary (P836): The project focuses on Nitride vertical devices with inverted built-in polarisation fields in structures grown on Ga-polar GaN substrates. To build such devices we will exploit unique features of n-p tunnel junctions (TJ). Growth of n-p TJ preceding the active region of the device allows to Incorporate the active region within the p-n configuration rather than the commonly used n-p one. This results in an inverted built-in electric field directi...)
Property / summary
 
The project focuses on Nitride vertical devices with inverted built-in polarisation fields in structures grown on Ga-polar GaN substrates. To build such devices we will exploit unique features of n-p tunnel junctions (TJ). Growth of n-p TJ preceding the active region of the device allows to Incorporate the active region within the p-n configuration rather than the commonly used n-p one. This results in an inverted built-in electric field direction inside the active region. Additionally, such devices will profit from having the n-type layer on the top. We will show that both features can lead to new applications of light emitting devices, laser diodes and transistors. Unique capabilities of the plasma-assisted molecular beam epitaxy system (high growth rate nitrogen plasma source, high Mg flux cell and Ge doping) installed in Warsaw will be crucial for samples growth. Project will be carried out in collaboration with groups at Cornell University and Wroclaw University of Technology. (English)
Property / summary: The project focuses on Nitride vertical devices with inverted built-in polarisation fields in structures grown on Ga-polar GaN substrates. To build such devices we will exploit unique features of n-p tunnel junctions (TJ). Growth of n-p TJ preceding the active region of the device allows to Incorporate the active region within the p-n configuration rather than the commonly used n-p one. This results in an inverted built-in electric field direction inside the active region. Additionally, such devices will profit from having the n-type layer on the top. We will show that both features can lead to new applications of light emitting devices, laser diodes and transistors. Unique capabilities of the plasma-assisted molecular beam epitaxy system (high growth rate nitrogen plasma source, high Mg flux cell and Ge doping) installed in Warsaw will be crucial for samples growth. Project will be carried out in collaboration with groups at Cornell University and Wroclaw University of Technology. (English) / rank
 
Normal rank
Property / summary: The project focuses on Nitride vertical devices with inverted built-in polarisation fields in structures grown on Ga-polar GaN substrates. To build such devices we will exploit unique features of n-p tunnel junctions (TJ). Growth of n-p TJ preceding the active region of the device allows to Incorporate the active region within the p-n configuration rather than the commonly used n-p one. This results in an inverted built-in electric field direction inside the active region. Additionally, such devices will profit from having the n-type layer on the top. We will show that both features can lead to new applications of light emitting devices, laser diodes and transistors. Unique capabilities of the plasma-assisted molecular beam epitaxy system (high growth rate nitrogen plasma source, high Mg flux cell and Ge doping) installed in Warsaw will be crucial for samples growth. Project will be carried out in collaboration with groups at Cornell University and Wroclaw University of Technology. (English) / qualifier
 
point in time: 14 October 2020
Timestamp+2020-10-14T00:00:00Z
Timezone+00:00
CalendarGregorian
Precision1 day
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After0

Revision as of 12:36, 14 October 2020

Project in Poland financed by DG Regio
Language Label Description Also known as
English
Polarity Engineering in Nitride Heterostructures
Project in Poland financed by DG Regio

    Statements

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    798,555.0 zloty
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    191,653.20 Euro
    13 January 2020
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    798,555.0 zloty
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    191,653.20 Euro
    13 January 2020
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    100.0 percent
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    1 October 2018
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    30 September 2020
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    INSTYTUT WYSOKICH CIŚNIEŃ POLSKIEJ AKADEMII NAUK
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    The project focuses on nitride vertical devices with inverted built-in polarization fields in structures grown on Ga-polar GaN substrates. To build such devices we will exploit unique features of n-p tunnel junctions (TJ). Growth of n-p TJ preceding the active region of the device allows to incorporate the active region within the p-n configuration rather than the commonly used n-p one. This results in an inverted built-in electric field direction inside the active region. Additionally, such devices will profit from having the n-type layer on the top. We will show that both features can lead to new applications of light emitting devices, laser diodes and transistors. Unique capabilities of the plasma-assisted molecular beam epitaxy system (high growth rate nitrogen plasma source, high Mg flux cell and Ge doping) installed in Warsaw will be crucial for samples growth. Project will be carried out in collaboration with groups at Cornell University and Wroclaw University of Technology. (Polish)
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    The project focuses on Nitride vertical devices with inverted built-in polarisation fields in structures grown on Ga-polar GaN substrates. To build such devices we will exploit unique features of n-p tunnel junctions (TJ). Growth of n-p TJ preceding the active region of the device allows to Incorporate the active region within the p-n configuration rather than the commonly used n-p one. This results in an inverted built-in electric field direction inside the active region. Additionally, such devices will profit from having the n-type layer on the top. We will show that both features can lead to new applications of light emitting devices, laser diodes and transistors. Unique capabilities of the plasma-assisted molecular beam epitaxy system (high growth rate nitrogen plasma source, high Mg flux cell and Ge doping) installed in Warsaw will be crucial for samples growth. Project will be carried out in collaboration with groups at Cornell University and Wroclaw University of Technology. (English)
    14 October 2020
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    Identifiers

    POIR.04.04.00-00-5D5B/18
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