Material Gain Engineering in Staggered Polar AlGaN/AlN Quantum Wells Dedicated for Deep UV Lasers

Gładysiewicz, M.; Hommel, D.; Kudrawiec, R.

doi:10.1109/jstqe.2019.2950802

Cited by 3 publications

(7 citation statements)

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“…In the context of studies reported in this work, the engineering of QW width in broad range can be also very interesting for staggered polar GaInN/GaN and AlGaN/AlN QWs. So far, large widths were not considered for staggered QWs as a drastic decrease in gain with increasing QW width was observed [59]. Since this polar QW system is non-intuitive, considering large widths in staggered QWs can lead to unexpected results, as shown in this paper for rectangular QWs.…”

Section: Aln Capmentioning

confidence: 92%

“…Figure 5 shows spectra of the TM mode of the material gain calculated for Al0.8Ga0.2N/AlN QWs of different widths at the carrier concentrations of 2.5 and 3.0×10 19 cm -3 . In contrast to the Ga0.8In0.2N/GaN QW, the fundamental transition in this QW is with TM polarization [59] and therefore the TM mode of the material gain is plotted in this figure. The change in the spectral position and the intensity of gain peak is very similar to that observed for Ga0.8In0.2N/GaN QW.…”

Section: Aln Capmentioning

confidence: 99%

“…Therefore, it is a very interesting issue to carefully study material gain for GaInN and AlGaN over a wide range of widths. So far, gain calculations have been reported for GaInN and AlGaN QWs in several articles [45,[52][53][54][55][56][57][58][59], but for wide QWs such calculations have not been reported in these articles. The widest QWs, for which optical gain calculations have been reported so far, are the 9 nm AlGaN wells [60].…”

Section: Introductionmentioning

confidence: 99%

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Material Gain in Polar GaInN and AlGaN Quantum Wells: How to Overcome the ‘Dead’ Width for Light Emitters in These QW Systems?

Gładysiewicz

Skierbiszewski

Kudrawiec

2022

IEEE J. Select. Topics Quantum Electron.

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Abstract-Polar GaInN and AlGaN quantum wells (QWs) are widely used in light emitting diodes and laser diodes (LDs). However, the widths of such QWs are usually limited to a few nanometers in order to ensure a sufficiently large overlap between the wave functions of the ground electron and the ground hole state. By increasing the QW width we enter the area of 'dead' width where, the overlap of the electron and hole wave functions decreases almost to zero and the luminescence efficiency drastically deteriorates. Therefore, it is assumed that wide QWs are not suitable for light emitters and very wide (8-15 nm) QWs are not considered as a promising gain medium for LDs. Hence such QWs are very rarely studied both experimentally and theoretically. In this work the material gain is calculated for Ga0.8In0.2N/GaN and Al0.8Ga0.2N/AlN QWs with a width varying in the range of 2-15 nm. We observed that the material gain at fixed carrier concentration for these QWs drops to zero with the increase in the QW width and reaches negative values in the width range of ~4-8 nm even for high carrier concentrations, but after exceeding a certain width to ~8-12 nm it begins to increase rapidly and reaches the values greater than those observed for narrow QWs. This phenomenon is related to the screening of the built-in electric field by carriers, which is easier for wide QWs, and the reduction of the distance between the energy levels for electrons and holes. For the latter reason, optical transitions between higher energy states make a very significant contribution to the positive material gain Index Terms-material gain, modeling, quantum wells, III-N

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Section: Aln Capmentioning

confidence: 92%

Section: Aln Capmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Material Gain in Polar GaInN and AlGaN Quantum Wells: How to Overcome the ‘Dead’ Width for Light Emitters in These QW Systems?

Gładysiewicz

Skierbiszewski

Kudrawiec

2022

IEEE J. Select. Topics Quantum Electron.

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“…Quite often, staggered QWs have been considered. [18][19][20][21][22][23][24] In this case, it is possible to obtain a better ground-state electron-hole overlap with appropriate polarization engineering, but the total thickness of the step-like barriers and QW is still below 5 nm, [18][19][20][21] which is very far from the width typical of non-polar QWs in III-V semiconductors, that is, 8-15 nm. [25][26][27][28] In contrast, lasing for wide InGaN QWs has been demonstrated experimentally.…”

Section: Doi: 101002/apxr202200107mentioning

confidence: 99%

Theoretical and Experimental Studies on Material Gain for Wide Polar InGaN Quantum Well‐Mechanism Leading to Electric Field Screening and Lasing

Gładysiewicz

Kudrawiec

Muzioł

et al. 2023

Advanced Physics Research

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The width of polar InGaN quantum wells (QWs) is usually limited to a few nanometers to ensure a sufficient overlap between the wave functions of the ground electron and hole state. This paper presents the results of material gain measurements for thin (2.6 nm), wide (10.4 nm), and extremely wide (25 nm) InGaN QWs. The comparison of experimental data with theoretical predictions allows for correlation of the current density with the carrier concentration, which contributes to the positive material gain, and determination of the coefficients in the standard ABC model. It is shown that the mechanism in wide and narrow polar QWs that leads to electric field screening and lasing is different. For wide QWs, the optical transitions between excited states become dominant in the gain spectrum. The reason for such a gain mechanism is the built‐in electric field, which must first be screened. The ground electron and hole states play a very important role in the screening; however, their contribution to the material gain and lasing in wide QWs is very weak.

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“…Interestingly, the staggered MQW structure design has recently been demonstrated in InGaN-based blue LEDs [ 45 ], green LEDs [ 46 ], and AlGaN-based deep UV lasers [ 47 ]. Additionally, the optoelectronic characteristics of InGaN-based green micro-resonant cavity light-emitting diodes (µ-RCLEDs), which consist of a three-layer staggered InGaN MQWs, bottom nanoporous n-GaN DBRs, and top Ta 2 O 5 /SiO 2 DBRs, have been numerically investigated [ 48 ].…”

Section: Introductionmentioning

confidence: 99%

Design and Simulation of InGaN-Based Red Vertical-Cavity Surface-Emitting Lasers

Yu,

Huang,

Wang

et al. 2023

Micromachines

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We propose a highly polarized vertical-cavity surface-emitting laser (VCSEL) consisting of staggered InGaN multiple quantum wells (MQWs), with the resonance cavity and polarization enabled by a bottom nanoporous (NP) n-GaN distributed Bragg reflectors (DBRs), and top TiO2 high-index contrast gratings (HCGs). Optoelectronic simulations of the 612 nm VCSEL were systematically and numerically investigated. First, we investigated the influences of the NP DBR and HCG geometries on the optical reflectivity. Our results indicate that when there are more than 17 pairs of NP GaN DBRs with 60% air voids, the reflectance can be higher than 99.7%. Furthermore, the zeroth-order reflectivity decreases rapidly when the HCG’s period exceeds 518 nm. The optimal ratios of width-to-period (52.86 ± 1.5%) and height-to-period (35.35 ± 0.14%) were identified. The staggered MQW design also resulted in a relatively small blue shift of 5.44 nm in the emission wavelength under a high driving current. Lastly, we investigated the cavity mode wavelength and optical threshold gain of the VCSEL with a finite size of HCG. A large threshold gain difference of approximately 67.4–74% between the 0th and 1st order transverse modes can be obtained. The simulation results in this work provide a guideline for designing red VCSELs with high brightness and efficiency.

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Material Gain Engineering in Staggered Polar AlGaN/AlN Quantum Wells Dedicated for Deep UV Lasers

Cited by 3 publications

References 50 publications

Material Gain in Polar GaInN and AlGaN Quantum Wells: How to Overcome the ‘Dead’ Width for Light Emitters in These QW Systems?

Material Gain in Polar GaInN and AlGaN Quantum Wells: How to Overcome the ‘Dead’ Width for Light Emitters in These QW Systems?

Theoretical and Experimental Studies on Material Gain for Wide Polar InGaN Quantum Well‐Mechanism Leading to Electric Field Screening and Lasing

Design and Simulation of InGaN-Based Red Vertical-Cavity Surface-Emitting Lasers

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