Emergence of high quality sputtered III-nitride semiconductors and devices

Izyumskaya, N.; Avrutin, Vitaliy; Ding, Kai; Özgür, Ü.; Morkoç̌, H.; Fujioka, Hiroshi

doi:10.1088/1361-6641/ab3374

Cited by 33 publications

(24 citation statements)

References 163 publications

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“…[1] In particular, AlInN alloys are special candidates for power electronics, highly efficient emitters, optoelectronic devices, and solar cells. [2][3][4][5][6][7][8] In that sense, radio-frequency (RF) magnetron sputtering allows the deposition of large-area and single-phase AlInN material using this low-cost and low-temperature technology exportable to the industry.…”

Section: Introductionmentioning

confidence: 99%

“…III‐Nitride semiconductors are interesting materials for the development of novel devices due to their direct bandgap energy tunable from the infrared (0.7 eV) for InN to the UV (6.2 eV) for AlN, their strong chemical and temperature endurance, and their radiation hardness . In particular, AlInN alloys are special candidates for power electronics, highly efficient emitters, optoelectronic devices, and solar cells . In that sense, radio‐frequency (RF) magnetron sputtering allows the deposition of large‐area and single‐phase AlInN material using this low‐cost and low‐temperature technology exportable to the industry.…”

Section: Introductionmentioning

confidence: 99%

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Low‐to‐Mid Al Content (x = 0–0.56) Al_xIn_1−xN Layers Deposited on Si(100) by Radio‐Frequency Sputtering

Blasco

Valdueza-Felip

Montero

et al. 2020

Physica Status Solidi (b)

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Radio‐frequency (RF) sputtering is a low‐cost technique for the deposition of large‐area single‐phase AlInN on silicon layers with application in photovoltaic devices. Here, the effect of the Al mole fraction x from 0 to 0.56 on the structural, morphological, electrical, and optical properties of n‐AlxIn1−xN layers deposited at 550 ºC on p‐Si(100) by RF sputtering is studied. X‐ray diffraction data show a wurtzite structure oriented along the c‐axis in all samples, where the full width at half maximum of the rocking curve around the InN (0002) diffraction peak decreases from ≈9° to ≈3° while incorporating Al to the AlInN layer. The root‐mean‐square surface roughness, estimated from atomic force microscopy, evolves from 20 nm for InN to 1.5 nm for Al0.56In0.44N. Low‐temperature photoluminescence spectra show a blueshift of the emission energy from 1.59 eV (779 nm) for InN to 1.82 eV (681 nm) for Al0.35In0.65N according to the Al content rise. Hall effect measurements of AlxIn1−xN (0 < x < 0.35) on sapphire samples grown simultaneously point to a residual n‐type carrier concentration in the 1021 cm−3 range. The developed n‐AlInN/p‐Si junctions present promising material properties to explore their performance operating as solar cell devices.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Low‐to‐Mid Al Content (x = 0–0.56) Al_xIn_1−xN Layers Deposited on Si(100) by Radio‐Frequency Sputtering

Blasco

Valdueza-Felip

Montero

et al. 2020

Physica Status Solidi (b)

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“…To date, basic methods to fabricate various heterostructures for device applications are metal-organic vapor phase epitaxy, metal organic chemical vapor deposition and molecular beam epitaxy [1][2][3]. Many of these deposition techniques are difficult to apply over a large area and are expensive due to complexity of the apparatus used.…”

Section: Introductionmentioning

confidence: 99%

Determination of crystallization conditions of Ge/GaAs heterostructures in scanning LPE method

Tsybulenko¹,

str.²,

Shutov³

et al. 2020

SPQEO

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We carried out the modelling of separate technological stages of scanning liquid phase epitaxy (SLPE) technique: wetting the substrate by the solution-melt using Ampere force, growing the epitaxial layer during a short-time contact between the substrate and solution-melt, and removing the solution-melt from the substrate using Ampere force as well. The modelling was carried out for the case of Ge layers growing on GaAs substrate from GaGe solution-melt at the temperature 500 °C. We have ascertained that the Peltier effect and Joule heating practically have no effect on the growth pattern and under certain conditions could be even diminished. The influence of electromigration and convection in the solution-melt can be neglected. It has been shown that the basic technological parameters of SLPE process are as follows: the initial temperatures and sizes of the substrate and the growing vessel, the conditions of heat removal from the substrate back side and the time of the process. It has been also shown that the major contribution into the epitaxial layer thickness distribution over the substrate surface has been made by the heat distribution in the cooled substrate.

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“…Although many research works on SAG-GaN NRs have been done in the past decade for MBE systems, study on MSE-SAG-GaN NRs is still limited due to the difficulty in handling liquid Ga sputtering source and in developing a proper nanopatterning process [34,35]. Magnetron sputter epitaxy (MSE) is a versatile NR growth technique with multiple distinct advantages, including easy integration on an industrial platform, reproducibility, smaller cost, and the absence of toxic precursors [35,36]. Previous works in a MBE-based system have shown that the effective Ga/N ratio is crucial to achieve high selectivity and high growth rate of SAG nanorods [15].…”

Section: Introductionmentioning

confidence: 99%

High-Selectivity Growth of GaN Nanorod Arrays by Liquid-Target Magnetron Sputter Epitaxy

et al. 2020

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Selective-area grown, catalyst-free GaN nanorod (NR) arrays grown on Si substrates have been realized using liquid-target reactive magnetron sputter epitaxy (MSE). Focused ion beam lithography (FIBL) was applied to pattern Si substrates with TiNx masks. A liquid Ga target was sputtered in a mixture gas of Ar and N2, ranging the N2 partial pressure (PN₂) ratio from 100% to 50%. The growth of NRs shows a strong correlation with PN₂ on the selectivity, coalescence, and growth rate of NRs in both radial and axial directions. The growth rate of NRs formed inside the nanoholes increases monotonically with PN₂. The PN₂ ratio between 80% and 90% was found to render both a high growth rate and high selectivity. When the PN₂ ratio was below 80%, multiple NRs were formed in the nanoholes. For a PN₂ ratio higher than 90%, parasitic NRs were grown on the mask. An observed dependence of growth behavior upon the PN₂ ratio is attributed to a change in the effective Ga/N ratio on the substrate surface, as an effect of impinging reactive species, surface diffusivity, and residence time of adatoms. The mechanism of NR growth control was further investigated by studying the effect of nanoholes array pitch and growth temperature. The surface diffusion and the direct impingement of adatoms were found to be the dominant factors affecting the lateral and axial growth rates of NR, respectively, which were well elucidated by the collection area model.

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Emergence of high quality sputtered III-nitride semiconductors and devices

Cited by 33 publications

References 163 publications

Low‐to‐Mid Al Content (x = 0–0.56) Al_xIn_1−xN Layers Deposited on Si(100) by Radio‐Frequency Sputtering

Low‐to‐Mid Al Content (x = 0–0.56) Al_xIn_1−xN Layers Deposited on Si(100) by Radio‐Frequency Sputtering

Determination of crystallization conditions of Ge/GaAs heterostructures in scanning LPE method

High-Selectivity Growth of GaN Nanorod Arrays by Liquid-Target Magnetron Sputter Epitaxy

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Emergence of high quality sputtered III-nitride semiconductors and devices

Cited by 33 publications

References 163 publications

Low‐to‐Mid Al Content (x = 0–0.56) AlxIn1−xN Layers Deposited on Si(100) by Radio‐Frequency Sputtering

Low‐to‐Mid Al Content (x = 0–0.56) AlxIn1−xN Layers Deposited on Si(100) by Radio‐Frequency Sputtering

Determination of crystallization conditions of Ge/GaAs heterostructures in scanning LPE method

High-Selectivity Growth of GaN Nanorod Arrays by Liquid-Target Magnetron Sputter Epitaxy

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Low‐to‐Mid Al Content (x = 0–0.56) Al_xIn_1−xN Layers Deposited on Si(100) by Radio‐Frequency Sputtering

Low‐to‐Mid Al Content (x = 0–0.56) Al_xIn_1−xN Layers Deposited on Si(100) by Radio‐Frequency Sputtering