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Reduced Dislocation Density of Non-Polar GaN Grown by Hydride Vapor Phase Epitaxy

Technology Benefits

Significantly improves film quality by allowing fabrication of enhanced GaN substrate layers for subsequent non-polar device fabrication; Greatly improves subsequent device performance.

Technology Application

Fabrication of low-dislocation density GaN by HVPE. This technology is available for a non-exclusive license. See below for a selection of the patents and patent applications related to this invention. Please inquire for full patent portfolio status.

Detailed Technology Description

Scientists at the University of California have developed a novel method for producing low-dislocation density non-polar GaN by hydride vapor phase epitaxy (HVPE). This invention complements the method for producing thick planar films of a-plane GaN by HVPE (UC Case 2003-225) by allowing single-step fabrication of reduced defect density material.

Supplementary Information

Patent Number: US7220658B2
Application Number: US2003537644A
Inventor: Haskell, Benjamin A | Craven, Michael D. | Fini, Paul T. | DenBaars, Steven P. | Speck, James S. | Nakamura, Shuji
Priority Date: 16 Dec 2002
Priority Number: US7220658B2
Application Date: 6 Jun 2005
Publication Date: 22 May 2007
IPC Current: H01L002120 | C30B002502 | H01L0021205
US Class: 438481 | 257E21097 | 257E21113 | 257E21131 | 257E21132
Assignee Applicant: The Regents of the University of California
Title: Growth of reduced dislocation density non-polar gallium nitride by hydride vapor phase epitaxy
Usefulness: Growth of reduced dislocation density non-polar gallium nitride by hydride vapor phase epitaxy
Summary: For manufacturing free-standing a-plane GaN film in the manufacture of laser diode, light emitting diode or transistor (claimed).
Novelty: Performing a lateral hydride vapor phase epitaxial overgrowth of planar, non-planar, a-plane gallium nitride film useful for laser diode involves masking sapphire and over growing the film under reduced pressure using hydrogen carrier gas

Industry

Optics

Sub Category

LED/OLED

Application No.

7220658

Others

Background

Gallium nitride (GaN) and its ternary and quaternary compounds incorporating aluminum and indium (AlGaN, InGaN, AlInGaN) have proven useful in fabricating visible and ultraviolet optoelectronic devices and high-power electronic devices. GaN and its alloys are most stable in the hexagonal w'rtzite crystal structure. However, the positions of the gallium and nitrogen atoms in this structure leads to polarization of the GaN crystals along the c-axis. Virtually all GaN-based devices are grown parallel to the polar c-axis, due to the relative ease of growing planar Ga-face planes. In addition, strain at the interfaces between adjacent dissimilar layers causes piezoelectric polarization and subsequent charge separation. These polarization effects decrease the likelihood of electron and hole interaction, which is essential for the operation of light-emitting devices. As a result, eliminating these polarization effects inherent to c-axis oriented devices could greatly enhance the efficiency of GaN light-emitting devices. In addition, defect densities in directly grown GaN films are much higher that those found in more traditional III/V semiconductor systems, such as the arsenides and phosphides.

Related Technologies

• Growth of Planar, Non-Polar, A-Plane GaN by Hydride Vapor Phase Epitaxy

Additional Technologies by these Inventors

• Growth of Planar, Non-Polar, A-Plane GaN by Hydride Vapor Phase Epitaxy
• Nonpolar (Al, B, In, Ga)N Quantum Well Design
• Improved Manufacturing of Semiconductor Lasers
• Cleaved Facet Edge-Emitting Laser Diodes Grown on Semipolar GaN
• Etching Technique for the Fabrication of Thin (Al, In, Ga)N Layers
• Enhancing Growth of Semipolar (Al,In,Ga,B)N Films via MOCVD
• GaN-Based Thermoelectric Device for Micro-Power Generation
• Growth of High-Quality, Thick, Non-Polar M-Plane GaN Films
• Method for Growing High-Quality Group III-Nitride Crystals
• Growth of Planar Semi-Polar Gallium Nitride
• Defect Reduction of Non-Polar and Semi-Polar III-Nitrides
• MOCVD Growth of Planar Non-Polar M-Plane Gallium Nitride
• Lateral Growth Method for Defect Reduction of Semipolar Nitride Films
• Low Temperature Deposition of Magnesium Doped Nitride Films
• Growth of Polyhedron-Shaped Gallium Nitride Bulk Crystals
• Improved Manufacturing of Solid State Lasers via Patterning of Photonic Crystals
• Control of Photoelectrochemical (PEC) Etching by Modification of the Local Electrochemical Potential of the Semiconductor Structure
• Phosphor-Free White Light Source
• Single or Multi-Color High Efficiency LED by Growth Over a Patterned Substrate
• High Efficiency LED with Optimized Photonic Crystal Extractor
• Packaging Technique for the Fabrication of Polarized Light Emitting Diodes
• LED Device Structures with Minimized Light Re-Absorption
• (In,Ga,Al)N Optoelectronic Devices with Thicker Active Layers for Improved Performance
• Oxyfluoride Phosphors for Use in White Light LEDs
• III-V Nitride Device Structures on Patterned Substrates
• Growth of Semipolar III-V Nitride Films with Lower Defect Density
• Improved GaN Substrates Prepared with Ammonothermal Growth
• Enhanced Optical Polarization of Nitride LEDs by Increased Indium Incorporation
• Semipolar-Based Yellow, Green, Blue LEDs with Improved Performance
• Hexagonal Wurtzite Type Epitaxial Layer with a Low Alkali-Metal Concentration
• Photoelectrochemical Etching Of P-Type Semiconductor Heterostructures
• Photoelectrochemical Etching for Chip Shaping Of LEDs
• Highly Efficient Blue-Violet III-Nitride Semipolar Laser Diodes
• Method for Manufacturing Improved III-Nitride LEDs and Laser Diodes: Monolithic Integration of Optically Pumped and Electrically Injected III-Nitride LEDs
• Defect Reduction in GaN films using in-situ SiNx Nanomask
• Semi-polar LED/LD Devices on Relaxed Template with Misfit Dislocation at Hetero-interface
• Limiting Strain-Relaxation in III-Nitride Heterostructures by Substrate Patterning
• Suppression of Defect Formation and Increase in Critical Thickness by Silicon Doping
• High Efficiency Semipolar AlGaN-Cladding-Free Laser Diodes
• Low-Cost Zinc Oxide for High-Power-Output, GaN-Based LEDs (UC Case 2010-183)
• Low-Cost Zinc Oxide for High-Power-Output, GaN-Based LEDs (UC Case 2010-150)
• Nonpolar III-Nitride LEDs With Long Wavelength Emission
• Method for Growing Self-Assembled Quantum Dot Lattices
• Method for Increasing GaN Substrate Area in Nitride Devices
• Flexible Arrays of MicroLEDs using the Photoelectrochemical (PEC) Liftoff Technique
• Optimization of Laser Bar Orientation for Nonpolar Laser Diodes
• UV Optoelectronic Devices Based on Nonpolar and Semi-polar AlInN and AlInGaN Alloys
• Low-Droop LED Structure on GaN Semi-polar Substrates
• Improved Fabrication of Nonpolar InGaN Thin Films, Heterostructures, and Devices
• Growth of High-Performance M-plane GaN Optical Devices
• Method for Enhancing Growth of Semipolar Nitride Devices
• Transparent Mirrorless (TML) LEDs
• Solid Solution Phosphors for Use in Solid State White Lighting Applications
• Technique for the Nitride Growth of Semipolar Thin Films, Heterostructures, and Semiconductor Devices
• Planar, Nonpolar M-Plane III-Nitride Films Grown on Miscut Substrates
• High-Efficiency, Mirrorless Non-Polar and Semi-Polar Light Emitting Devices
• High Light Extraction Efficiency III-Nitride LED
• Tunable White Light Based on Polarization-Sensitive LEDs
• Method for Improved Surface of (Ga,Al,In,B)N Films on Nonpolar or Semipolar Subtrates
• Improved Anisotropic Strain Control in Semipolar Nitride Devices
• III-Nitride Tunnel Junction with Modified Interface
• Enhanced Light Extraction LED with a Tunnel Junction Contact Wafer Bonded to a Conductive Oxide
• Increased Light Extraction with Multistep Deposition of ZnO on GaN
• Hybrid Growth Method for Improved III-Nitride Tunnel Junction Devices
• Calcium Impurity Reduction for Improved Light-Emitting Devices
• Contact Architectures for Tunnel Junction Devices
• New Blue Phosphor for High Heat Applications
• Internal Heating for Ammonothermal Growth of Group-III Nitride Crystals
• Methods for Fabricating III-Nitride Tunnel Junction Devices
• Multifaceted III-Nitride Surface-Emitting Laser
• Laser Diode System For Horticultural Lighting
• Fabricating Nitride Layers
• Reduction in Leakage Current and Increase in Efficiency of III-Nitride MicroLEDS
• Vertical Cavity Surface-Emitting Lasers with Continuous Wave Operation
• Laser Lighting System Incorporating an Additional Scattered Laser

Tech ID/UC Case

10267/2003-224-0

Related Cases

2003-224-0

*Abstract

A novel method for producing low-dislocation density non-polar GaN by hydride vapor phase epitaxy (HVPE).

*IP Issue Date

May 22, 2007

*Principal Investigator

Name: Michael Craven

Department:

Name: Steven DenBaars

Department:

Name: Paul Fini

Department:

Name: Benjamin Haskell

Department:

Name: Shuji Nakamura

Department:

Name: James Speck

Department:

Country/Region

USA