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公开(公告)号:US10685835B2
公开(公告)日:2020-06-16
申请号:US15773864
申请日:2016-11-01
Applicant: The Regents of the University of California
Inventor: Benjamin P. Yonkee , Erin C. Young , John T. Leonard , Tal Margalith , James S. Speck , Steven P. DenBaars , Shuji Nakamura
IPC: H01L21/00 , H01L29/00 , H01L31/18 , H01L33/00 , H01L21/02 , H01L29/15 , H01L29/20 , H01L29/207 , H01L29/36 , H01L29/885 , H01L31/0304 , H01L31/0352 , H01L33/06 , H01L33/32 , H01L29/88 , H01L33/04
Abstract: A III-nitride tunnel junction with a modified p-n interface, wherein the modified p-n interface includes a delta-doped layer to reduce tunneling resistance. The delta-doped layer may be doped using donor atoms comprised of Oxygen (O), Germanium (Ge) or Silicon (Si); acceptor atoms comprised of Magnesium (Mg) or Zinc (Zn); or impurities comprised of Iron (Fe) or Carbon (C).
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2.发明申请ANISOTROPIC STRAIN CONTROL IN SEMIPOLAR NITRIDE QUANTUM WELLS BY PARTIALLY OR FULLY RELAXED ALUMINUM INDIUM GALLIUM NITRIDE LAYERS WITH MISFIT DISLOCATIONS 有权通过部分或完全放松的铝氮化镓氮化物层与杂质分离的二氧化氮量子阱中的各向异性应变控制公开(公告)号:US20130259080A1
公开(公告)日:2013-10-03
申请号:US13904908
申请日:2013-05-29
Applicant: The Regents of the University of California
Inventor: Hiroaki Ohta , Feng Wu , Anurag Tyagi , Arpan Chakraborty , James S. Speck , Steven P. DenBaars , Shuji Nakamura , Erin C. Young
CPC classification number: H01S5/34333 , B82Y20/00 , H01L21/02389 , H01L21/0242 , H01L21/02433 , H01L21/0254 , H01L33/0075 , H01L33/12 , H01L33/16 , H01L33/32 , H01S5/2201 , H01S5/32 , H01S5/3201 , H01S5/3202 , H01S5/3403 , H01S5/3425 , H01S2301/173
Abstract: An epitaxial structure for a III-Nitride based optical device, comprising an active layer with anisotropic strain on an underlying layer, where a lattice constant and strain in the underlying layer are partially or fully relaxed in at least one direction due to a presence of misfit dislocations, so that the anisotropic strain in the active layer is modulated by the underlying layer.
Abstract translation: 用于基于III-Nitride的光学器件的外延结构,其包括在下层上具有各向异性应变的活性层,其中由于存在失配而使底层中的晶格常数和应变在至少一个方向上部分或完全松弛 位错,使得有源层中的各向异性应变被下层调制。
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3.发明授权公开(公告)号:US11164997B2
公开(公告)日:2021-11-02
申请号:US16320924
申请日:2017-08-17
Applicant: THE REGENTS OF THE UNIVERSITY OF CALIFORNIA
Inventor: Benjamin P. Yonkee , Erin C. Young , James S. Speck , Steven P. DenBaars , Shuji Nakamura
Abstract: A III-Nitride LED which utilizes n-type III-Nitride layers for current spreading on both sides of the device. A multilayer dielectric coating is used underneath the wire bond pads, both LED contacts are deposited in one step, and the p-side wire bond pad is moved off of the mesa. The LED has a wall plug efficiency or External Quantum Efficiency (EQE) over 70%, a fractional EQE droop of less than 7% at 20 A/cm2 drive current and less than 15% at 35 A/cm2 drive current. The LEDs can be patterned into an LED array and each LED can have an edge dimension of between 5 and 50 μm. The LED emission wavelength can be below 400 nm and aluminum can be added to the n-type III-Nitride layers such that the bandgap of the n-type III-nitride layers is larger than the LED emission photon energy.
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4.发明申请ANISOTROPIC STRAIN CONTROL IN SEMIPOLAR NITRIDE QUANTUM WELLS BY PARTIALLY OR FULLY RELAXED ALUMINUM INDIUM GALLIUM NITRIDE LAYERS WITH MISFIT DISLOCATIONS 审中-公开通过部分或完全放松的铝氮化镓氮化物层与杂质分离的二氧化氮量子阱中的各向异性应变控制公开(公告)号:US20140376584A1
公开(公告)日:2014-12-25
申请号:US14482760
申请日:2014-09-10
Applicant: The Regents of the University of California
Inventor: Hiroaki Ohta , Feng Wu , Anurag Tyagi , Arpan Chakraborty , James S. Speck , Steven P. DenBaars , Shuji Nakamura , Erin C. Young
CPC classification number: H01S5/34333 , B82Y20/00 , H01L21/02389 , H01L21/0242 , H01L21/02433 , H01L21/0254 , H01L33/0075 , H01L33/12 , H01L33/16 , H01L33/32 , H01S5/2201 , H01S5/32 , H01S5/3201 , H01S5/3202 , H01S5/3403 , H01S5/3425 , H01S2301/173
Abstract: An epitaxial structure for a III-Nitride based optical device, comprising an active layer with anisotropic strain on an underlying layer, where a lattice constant and strain in the underlying layer are partially or fully relaxed in at least one direction due to a presence of misfit dislocations, so that the anisotropic strain in the active layer is modulated by the underlying layer.
Abstract translation: 用于基于III-Nitride的光学器件的外延结构,其包括在下层上具有各向异性应变的活性层,其中由于存在失配而使底层中的晶格常数和应变在至少一个方向上部分或完全松弛 位错,使得有源层中的各向异性应变被下层调制。
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公开(公告)号:US11348908B2
公开(公告)日:2022-05-31
申请号:US16325709
申请日:2017-08-17
Applicant: THE REGENTS OF THE UNIVERSITY OF CALIFORNIA
Inventor: Benjamin P. Yonkee , Erin C. Young , James S. Speck , Steven P. DenBaars , Shuji Nakamura
Abstract: A flip chip III-Nitride LED which utilizes a dielectric coating backed by a metallic reflector (e.g., aluminum or silver). High reflectivity and low resistance contacts for optoelectronic devices. Low ESD rating optoelectronic devices. A VCSEL comprising a tunnel junction for current and optical confinement.
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Patent Agency Ranking
6.发明申请公开(公告)号:US20200335663A1
公开(公告)日:2020-10-22
申请号:US16075949
申请日:2017-02-06
Applicant: The Regents of the University of California
Inventor: Asad J. Mughal , Stacy J. Kowsz , Robert M. Farrell , Benjamin P. Yonkee , Erin C. Young , Christopher D. Pynn , Tal Margalith , James S. Speck , Shuji Nakamura , Steven P. DenBaars
Abstract: A III-nitride optoelectronic device includes at least one n-type layer, an active region grown on or above the n-type layer, at least one p-type layer grown on or above the active region, and a tunnel junction grown on or above the p-type layer. A conductive oxide may be wafer bonded on or above the tunnel junction, wherein the conductive oxide comprises a transparent conductor and may contain light extraction features on its non-bonded face. The tunnel junction also enables monolithic incorporation of electrically-injected and optically-pumped III-nitride layers, wherein the optically-pumped III-nitride layers comprise high-indium-content III-nitride layers formed as quantum wells (QWs) that are grown on or above the tunnel junction. The optically-pumped high-indium-content III-nitride layers emit light at a longer wavelength than the electrically-injected III-nitride layers.
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7.发明申请公开(公告)号:US20190165213A1
公开(公告)日:2019-05-30
申请号:US16320924
申请日:2017-08-17
Applicant: THE REGENTS OF THE UNIVERSITY OF CALIFORNIA
Inventor: Benjamin P. Yonkee , Erin C. Young , James S. Speck , Steven P. DenBaars , Shuji Nakamura
Abstract: A III-Nitride LED which utilizes n-type III-Nitride layers for current spreading on both sides of the device. A multilayer dielectric coating is used underneath the wire bond pads, both LED contacts are deposited in one step, and the p-side wire bond pad is moved off of the mesa. The LED has a wall plug efficiency or External Quantum Efficiency (EQE) over 70%, a fractional EQE droop of less than 7% at 20 A/cm2 drive current and less than 15% at 35 A/cm2 drive current. The LEDs can be patterned into an LED array and each LED can have an edge dimension of between 5 and 50 μm. The LED emission wavelength can be below 400 nm and aluminum can be added to the n-type III-Nitride layers such that the bandgap of the n-type III-nitride layers is larger than the LED emission photon energy.
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公开(公告)号:US11411137B2
公开(公告)日:2022-08-09
申请号:US16075949
申请日:2017-02-06
Applicant: The Regents of the University of California
Inventor: Asad J. Mughal , Stacy J. Kowsz , Robert M. Farrell , Benjamin P. Yonkee , Erin C. Young , Christopher D. Pynn , Tal Margalith , James S. Speck , Shuji Nakamura , Steven P. DenBaars
Abstract: A III-nitride optoelectronic device includes at least one n-type layer, an active region grown on or above the n-type layer, at least one p-type layer grown on or above the active region, and a tunnel junction grown on or above the p-type layer. A conductive oxide may be wafer bonded on or above the tunnel junction, wherein the conductive oxide comprises a transparent conductor and may contain light extraction features on its non-bonded face. The tunnel junction also enables monolithic incorporation of electrically-injected and optically-pumped III-nitride layers, wherein the optically-pumped III-nitride layers comprise high-indium-content III-nitride layers formed as quantum wells (QWs) that are grown on or above the tunnel junction. The optically-pumped high-indium-content III-nitride layers emit light at a longer wavelength than the electrically-injected III-nitride layers.
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公开(公告)号:US11217722B2
公开(公告)日:2022-01-04
申请号:US15743023
申请日:2016-07-11
Applicant: The Regents of the University of California
Inventor: Erin C. Young , Benjamin P. Yonkee , John T. Leonard , Tal Margalith , James S. Speck , Steven P. DenBaars , Shuji Nakamura
IPC: H01L21/02 , H01L33/00 , H01L33/32 , H01L33/14 , H01L21/00 , H01L31/0304 , C30B23/02 , C30B29/68 , H01S5/40 , C30B25/20 , H01L33/04 , C30B29/40 , H01S5/30 , H01L31/147 , H01L33/06 , H01S5/026 , H01S5/183 , H01S5/343
Abstract: A hybrid growth method for III-nitride tunnel junction devices uses metal-organic chemical vapor deposition (MOCVD) to grow one or more light-emitting or light-absorbing structures and ammonia-assisted or plasma-assisted molecular beam epitaxy (MBE) to grow one or more tunnel junctions. Unlike p-type gallium nitride (p-GaN) grown by MOCVD, p-GaN grown by MBE is conductive as grown, which allows for its use in a tunnel junction. Moreover, the doping limits of MBE materials are higher than MOCVD materials. The tunnel junctions can be used to incorporate multiple active regions into a single device. In addition, n-type GaN (n-GaN) can be used as a current spreading layer on both sides of the device, eliminating the need for a transparent conductive oxide (TCO) layer or a silver (Au) mirror.
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公开(公告)号:US20210104504A1
公开(公告)日:2021-04-08
申请号:US16325709
申请日:2017-08-17
Applicant: THE REGENTS OF THE UNIVERSITY OF CALIFORNIA
Inventor: Benjamin P. Yonkee , Erin C. Young , Charles Forman , John T. Leonard , SeungGeun Lee , Dan Cohen , Robert M. Farrell , Michael Iza , Burhan Saifaddin , Abdullah Almogbel , Humberto Foronda , James S. Speck , Steven P. DenBaars , Shuji Nakamura
Abstract: A flip chip III-Nitride LED which utilizes a dielectric coating backed by a metallic reflector (e.g., aluminum or silver). High reflectivity and low resistance contacts for optoelectronic devices. Low ESD rating optoelectronic devices. A VCSEL comprising a tunnel junction for current and optical confinement.
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