Characterization of hydrogen environment anisotropic thermal etching and application to GaN nanostructure fabrication

Kita, Ryo; Hachiya, Ryo; Mizutani, Tomoya; Furuhashi, Hiroki; Kikuchi, Akihiko

doi:10.7567/jjap.54.046501

Cited by 9 publications

(10 citation statements)

References 37 publications

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“…Conversely, the side facets of the m ‐axis nanowall LED structures had slanted jagged planes. These jagged planes remarkably appeared on the InGaN/GaN sample having a p‐GaN layer compared with the GaN‐only sample from our previous report . The lateral width of InGaN MQW ( W ) was estimated to be 61 and 59 nm for (a) a ‐axis nanowalls and (b) m ‐axis nanowalls, respectively.…”

Section: Resultsmentioning

confidence: 63%

“…We have reported the fabrication of fine GaN nanowall and nanopillar structures with a top width of 40 nm and a height of 180 nm using HEATE .…”

Section: Introductionmentioning

confidence: 99%

“…We focused on the top–down process as a promising technique for the fabrication of InGaN/GaN nanostructured LEDs (nano‐LEDs). Several studies on top–down InGaN/GaN nano‐LEDs have been conducted ; however, in most of the cases, the lateral size of the InGaN active layer was larger than 100 nm. The nanostructure effects appear more clearly as the lateral size decreases; however, simultaneously, the effects of etching damage such as nonradiative recombination deteriorate the device performance owing to increase in the surface‐to‐volume ratio.…”

Section: Introductionmentioning

confidence: 99%

“…In many cases, top–down InGaN/GaN nano‐LEDs require post wet‐etching processes to remove the regions damaged by etching . Recently, we have developed a new GaN‐etching technique known as hydrogen‐environment anisotropic thermal etching (HEATE) . HEATE is a low‐damage selective area anisotropic etching technique based on thermal decomposition of GaN under a hydrogen environment typically at approximately 850–1050 °C using SiO 2 masking.…”

Section: Introductionmentioning

confidence: 99%

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Fabrication of InGaN/GaN MQW nano‐LEDs by hydrogen‐environment anisotropic thermal etching

Ogawa

Hachiya

Mizutani

et al. 2016

Physica Status Solidi (a)

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III‐nitride semiconductor nanostructures are attractive materials for the realization of high‐performance and highly functional optoelectronic devices. In this study, we fabricated InGaN/GaN multiple quantum well (MQW) nanostructured light‐emitting diodes (nano‐LEDs) using hydrogen‐environment anisotropic thermal etching (HEATE). HEATE is a low‐damage anisotropic etching technique that is based on the thermal decomposition of (In)GaN under a low‐pressure hydrogen environment. The InGaN/GaN MQW nano‐LEDs showed good rectification characteristics and blue emission without any post treatment to remove all etching damage. The narrowest MQW lateral sizes of successfully fabricated nanowall and nanopillar LEDs were 87 and 70 nm, respectively. These LEDs are among the smallest InGaN/GaN‐based nano‐LEDs fabricated via a top–down process. Electroluminescence images of InGaN/GaN nano‐LEDs operated at 3 V. (a) An a‐axis honeycomb nanowall, (b) an m‐axis nanowall array, (c) an a‐axis nanowall array, and (d) a nanopillar array.

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Section: Resultsmentioning

confidence: 63%

“…We have reported the fabrication of fine GaN nanowall and nanopillar structures with a top width of 40 nm and a height of 180 nm using HEATE .…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Fabrication of InGaN/GaN MQW nano‐LEDs by hydrogen‐environment anisotropic thermal etching

Ogawa

Hachiya

Mizutani

et al. 2016

Physica Status Solidi (a)

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“…Dry etching with chlorinebased gases [14][15][16] is generally used for nanofabrication in GaN, but it has the disadvantages of considerable processing damage [17][18][19] and the need for expensive detoxification equipment due to the use of toxic gases. [20][21][22] We have developed a hydrogen environment anisotropic thermal etching (HEATE) method 23,24) for fabricating InGaN-based nanostructures, which can be performed with a simple equipment configuration and a thin (∼15 nm) SiO 2 film that acts as a good etching mask. The HEATE method can be implemented with a simple equipment configuration, and the thin SiO 2 mask enables ultrafine nanofabrication that is tens of nanometers in size.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of GaN topological photonic crystal membranes in the visible wavelength region by a combination process of HEATE and AlInN wet etching

Yoneta

Abe

Kudou

et al. 2022

Jpn. J. Appl. Phys.

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The fabrication technology for photonic crystals (PhCs) pertaining to the near-infrared region is mature, and the development of highly functional PhCs using low-symmetry nanoholes is rapidly progressing. In the visible region, InGaN/GaN systems that have good luminescent and electrical properties are the most promising candidate materials for such types of highly functional PhCs, but the development is not progressing. In this study, we report on the basic design parameters and a new fabrication method for InGaN/GaN-based PhC membranes by combining hydrogen environment anisotropic thermal etching (HEATE) based on hydrogen-assisted thermal decomposition and nitric acid wet etching of the AlInN sacrificial layer. Using this method, we fabricated high-quality InGaN/GaN multiple-quantum-well PhC membrane structures having six-membered rings of well-formed fine equilateral triangular nanoholes with a side length of 100 nm. Enhanced green room-temperature photoluminescence with an intensity nine times higher than that of as-grown wafers was observed for the PhC membrane.

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Etching Characteristics of Hydrogen Environment Anisotropic Thermal Etching for GaN‐Based Functional Photonic Devices

Honda,

Akimoto,

Kurabe

et al. 2024

Physica Status Solidi (a)

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InGaN/GaN‐based group‐III nitride semiconductors are the most promising candidate materials for highly functional active photonic devices in the visible region. Low‐damage nanoscale high‐precision etching with vertical facets is important for realizing photonic crystal (PhC) and optically integrated devices. Herein, the etching characteristics of GaN nanoholes using the hydrogen environment anisotropic thermal etching (HEATE) method, which is based on the hydrogen‐assisted thermal decomposition of GaN, are systematically demonstrated. It is found that high‐precision and vertical nanofabrication is possible at high etching temperature (≈1000 °C) and low hydrogen pressure conditions (<18 Pa). In GaN‐based visible topological PhCs composed of fine triangular nanoholes fabricated under these conditions, the photonic bands are observed to be in good agreement with the three‐dimensional finite‐difference time‐domain simulations, indicating the effectiveness of the HEATE method.

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Characterization of hydrogen environment anisotropic thermal etching and application to GaN nanostructure fabrication

Cited by 9 publications

References 37 publications

Fabrication of InGaN/GaN MQW nano‐LEDs by hydrogen‐environment anisotropic thermal etching

Fabrication of InGaN/GaN MQW nano‐LEDs by hydrogen‐environment anisotropic thermal etching

Fabrication of GaN topological photonic crystal membranes in the visible wavelength region by a combination process of HEATE and AlInN wet etching

Etching Characteristics of Hydrogen Environment Anisotropic Thermal Etching for GaN‐Based Functional Photonic Devices

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