Performance Improvement of GaN Based Laser Diode Using Pd/Ni/Au Metallization Ohmic Contact

Wang, Wenjie; Xie, Wuze; Deng, Zejia; Yang, H. T.; Liao, Mingle; Li, Junze; Luo, Xiaojia; Sun, Su-Qin; Zhao, Degang

doi:10.3390/coatings9050291

Cited by 16 publications

(8 citation statements)

References 52 publications

(66 reference statements)

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“…Due to one of the highest work function values among metallic elements, both Ni and Pd are used as materials or components for making electrical contacts with GaN. Electric contacts using Pd/Ni bilayers improve device performance [32]. The interfacial reaction between nickel and GaN can occur during annealing [33], which is a commonly used step for contact creation.…”

Section: Introductionmentioning

confidence: 99%

Properties of Bare and Thin-Film-Covered GaN(0001) Surfaces

Grodzicki

2021

Coatings

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In this paper, the surface properties of bare and film-covered gallium nitride (GaN) in wurtzite form, (0001) oriented, are summarized. Thin films of several elements—manganese, nickel, palladium, arsenic, and antimony—were formed by the physical vapor deposition method. The results of the bare surfaces, as well as the thin film/GaN(0001) phase boundaries presented, were characterized by X-ray and ultraviolet photoelectron spectroscopies (XPS, UPS). Basic information on the electronic properties of GaN(0001) surfaces are shown. Different behaviors of the thin films, after postdeposition annealing in ultrahigh vacuum conditions such as surface alloying and subsurface dissolving and desorbing, were found. The metal films formed surface alloys with gallium (MnGa, NiGa, PdGa), while the semimetal (As, Sb) layers easily evaporate from the GaN(0001) surface. However, the layer in direct contact with the substrate could react with it, modifying the surface properties of GaN(0001).

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Section: Introductionmentioning

confidence: 99%

Properties of Bare and Thin-Film-Covered GaN(0001) Surfaces

Grodzicki

2021

Coatings

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“…In recent decades, GaN-based laser diode has become a research interest in laser field due to its extensive applications in laser display, material processing, information storage, laser communication and other fields [1][2][3][4]. With the continuous improvement of epitaxial material growth technology, the photoelectric performance of GaN-based lasers has been greatly improved.…”

Section: Introductionmentioning

confidence: 99%

Effects of AlInGaN electron barrier layer with different aluminum components on the photoelectric properties of GaN-based laser

Wang,

Liao,

Luo

et al. 2024

Fifth International Conference on Optoelectronic Science and Materials (ICOSM 2023)

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The effects of AlInGaN electron barrier layer (EBL) on the photoelectric properties of gallium nitride laser with reduced polarization of different aluminum components is numerically simulated by crosslight software. Compared with the Al0.322In0.08Ga0.598N EBL, the Al0.447In0.174Ga0.379N EBL with higher Al component improves the photoelectric performance of laser, achieving lower threshold current and higher output power. The reason is that the use of Al0.447In0.174Ga0.379N electron barrier material with higher Al component further reduces the polarization effect, thus improving the hole injection efficiency and reducing the electron leakage. Simulation results reveal that the threshold current decreases from 25.3mA to 22.6mA, and the output power increases from 98.3mW to 155.9mW. At the same time, the optical field distribution of higher Al component EBL structure laser is more concentrated in the active region, which further reduces the absorption loss, so that the optical confinement factor increases from 1.14% to 1.2%, and the slope efficiency also increases from 0.77W/A to 1.18W/A.

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“…With the advantages of small size, high efficiency, long life, and fast response speed, GaN-based semiconductor laser is widely used in laser display, laser lighting, underwater communication, biomedicine, and other civil and military fields. [1][2][3][4][5][6][7][8] In particular, the GaN-based violet laser diodes (LDs) have attracted attention as a new laser source for high-density optical disk storage. [9,10] To realize such applications, high power GaN LD is significantly important.…”

Section: Introductionmentioning

confidence: 99%

Enhancing performance of GaN-based LDs by using GaN/InGaN asymmetric lower waveguide layers

Wang¹,

Liao²,

Yuan³

et al. 2022

Chinese Phys. B

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The effects of GaN/InGaN asymmetric lower waveguide (LWG) layers on photoelectrical properties of InGaN multiple quantum well laser diodes (LDs) with an emission wavelength around 416 nm are theoretically investigated by tuning the thickness and the Indium content of InGaN insertion layer (InGaN-IL) between the GaN lower waveguide layer and the quantum wells, which is achieved with the Crosslight Device Simulation Software(PIC3D, Crosslight Software Inc.). The optimal thickness and the Indium content of the InGaN-IL in lower waveguide layers are found to be 300 nm and 4%, respectively. The thickness of InGaN-IL predominantly affects the output power and the optical field distribution compared to that of the Indium content, and the highest output power achieved 1.25 times that of the reference structure (symmetric GaN waveguide), which is attributed to reduced optical absorption loss as well as the concentrated optical field nearby quantum wells. Furthermore, when the thickness and indium content of InGaN-IL reaches a higher level, the performance of asymmetric quantum wells LDs will be weakened rapidly due to the obvious decrease of optical confinement factor (OCF) related to the concentrated optical field in the lower waveguide.

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Performance Improvement of GaN Based Laser Diode Using Pd/Ni/Au Metallization Ohmic Contact

Cited by 16 publications

References 52 publications

Properties of Bare and Thin-Film-Covered GaN(0001) Surfaces

Properties of Bare and Thin-Film-Covered GaN(0001) Surfaces

Effects of AlInGaN electron barrier layer with different aluminum components on the photoelectric properties of GaN-based laser

Enhancing performance of GaN-based LDs by using GaN/InGaN asymmetric lower waveguide layers

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