InN-based heterojunction photodetector with extended infrared response

Hsu, Lewis; Kuo, Cheng-Tzu; Huang, Jen-Wei; Hsu, Shun Chieh; Lee, Hsin Ying; Kuo, Hao Chung; Lee, Po Tsung; Tsai, Yu Lin; Hwang, Yu-Chyi; Su, Chen Feng; He, Jr Hau; Lin, Shi‐Yow; Cheng, Yuh Jen; Lin, Chien Chung

doi:10.1364/oe.23.031150

Cited by 22 publications

(12 citation statements)

References 57 publications

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“…窒化インジウム(InN)は,窒化物半導体の中で最も電子質量が小さく(~ 0.055 m0) 1) バンドギャップが小さい(~ 0.65 eV) 2) ことから高速トランジスタ 3) や高周波デバイス 4) ,赤外受光デバイス 5) などへの応用が期待される．一方で, 格子整合する基板材料が不在であること 6) ,窒素の平衡蒸気圧が高く高温での成長が難しいこと 7) ,ストイキオメト Fig. 1(a)…”

Section: 緒言unclassified

Rf-Mbeを用いたファンデルワールスエピタキシーによるグラフェン構造への窒化インジウム結晶成長

Mouri

Arakawa

Ooe

et al. 2020

J. Soc. Mat. Sci., Japan

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We have studied van der Waals epitaxy of indium nitride (InN) on graphitic substrates using radio frequency plasma assisted molecular beam epitaxy (RF-MBE) and droplet elimination by radical ion beam (DERI) method. InN nanocrystals smaller than ~ 100 nm were densely grown on the single layer graphene supported on SiO2/Si while larger hexagonal shape nanocrystals larger than 500 nm were obtained on the thick graphite. Our result suggested that both defects on the graphitic substrate and flatness plays important role to limit the crystal size, such that these parameters act on the In droplet coverage at initial growth stage. With inserting aluminum nitride (AlN) buffer layer, the coalescent of these crystals can be improved and highly oriented wurtzite structure becomes dominant. These findings give the new insights for the improvement of the crystal growth of InN thin film.

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Section: 緒言unclassified

Rf-Mbeを用いたファンデルワールスエピタキシーによるグラフェン構造への窒化インジウム結晶成長

Mouri

Arakawa

Ooe

et al. 2020

J. Soc. Mat. Sci., Japan

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“…The above-mentioned technological problems hamper the study of InN properties. Despite this, considerable progress in device applications of epitaxial InN has been demonstrated recently, including the fabrication of infrared photodetectors 7 , thin-film transistors 8 , photovoltaic converters 9 , and a number of terahertz-range devices 10 , 11 . One of the possible ways to overcome the lattice mismatch problem is the formation of InN-based low-dimensional structures: nanowires, quantum dots, and quantum “pyramids” 12 , 13 , 14 .…”

Section: Introductionmentioning

confidence: 99%

Towards the indium nitride laser: obtaining infrared stimulated emission from planar monocrystalline InN structures

Andreev

Kudryavtsev

Yablonskiy

et al. 2018

Sci Rep

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The observation of a stimulated emission at interband transitions in monocrystalline n-InN layers under optical pumping is reported. The spectral position of the stimulated emission changes over a range of 1.64 to 1.9 μm with variations of free electron concentration in InN layers from 2·1019 cm−3 to 3·1017 cm−3. The main necessary conditions for achieving the stimulated emission from epitaxial InN layers are defined. In the best quality samples, a threshold excitation power density is obtained to be as low as 400 W/cm2 at T = 8 K and the stimulated emission is observed up to 215 K. In this way, the feasibility of InN-based lasers as well as the potentials of crystalline indium nitride as a promising photonic material are demonstrated.

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“…To date, the best results were obtained through epitaxial growth of InN on p-GaN by molecular beam epitaxy (MBE) [9]. From the point of view of optoelectronic device production, metalorganic vapor-phase epitaxy (MOVPE) is more suitable [10,11,12]. Nevertheless, MOVPE is restricted by the low decomposition rate of NH 3 , resulting in InN island growth on GaN, which deteriorates the quality of the InN films [13].…”

Section: Introductionmentioning

confidence: 99%

“…Nevertheless, MOVPE is restricted by the low decomposition rate of NH 3 , resulting in InN island growth on GaN, which deteriorates the quality of the InN films [13]. These nucleation islands also strongly affect the junction interface morphology by producing dislocation defects and causing inefficient photo-response of the devices (e.g., detectors, solar cells) [12].…”

Section: Introductionmentioning

confidence: 99%

Significant Carrier Extraction Enhancement at the Interface of an InN/p-GaN Heterojunction under Reverse Bias Voltage

et al. 2018

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In this paper, a superior-quality InN/p-GaN interface grown using pulsed metalorganic vapor-phase epitaxy (MOVPE) is demonstrated. The InN/p-GaN heterojunction interface based on high-quality InN (electron concentration 5.19 × 1018 cm−3 and mobility 980 cm2/(V s)) showed good rectifying behavior. The heterojunction depletion region width was estimated to be 22.8 nm and showed the ability for charge carrier extraction without external electrical field (unbiased). Under reverse bias, the external quantum efficiency (EQE) in the blue spectral region (300–550 nm) can be enhanced significantly and exceeds unity. Avalanche and carrier multiplication phenomena were used to interpret the exclusive photoelectric features of the InN/p-GaN heterojunction behavior.

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InN-based heterojunction photodetector with extended infrared response

Cited by 22 publications

References 57 publications

Rf-Mbeを用いたファンデルワールスエピタキシーによるグラフェン構造への窒化インジウム結晶成長

Rf-Mbeを用いたファンデルワールスエピタキシーによるグラフェン構造への窒化インジウム結晶成長

Towards the indium nitride laser: obtaining infrared stimulated emission from planar monocrystalline InN structures

Significant Carrier Extraction Enhancement at the Interface of an InN/p-GaN Heterojunction under Reverse Bias Voltage

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