Green to blue polarization compensated c-axis oriented multi-quantum wells by AlGaInN barrier layers

Dadgar, A.; Groh, Lars; Metzner, Sebastian; Neugebauer, Silvio; Bläsing, J.; Hempel, T.; Bertram, F.; Christen, J.; Krost, A.; Andreev, Zhelio; Witzigmann, Bernd

doi:10.1063/1.4793185

Cited by 14 publications

(11 citation statements)

References 16 publications

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“…In sample series A (Fig. (a)) the PL peak position of the MQW emission shifts from 580 to 490 nm (∼393 meV) for samples A0–A4 and is comparable to the luminescence shift found in our previous work . Samples A2 and A4 exhibit an additional PL signal at 408 nm (3.039 eV) and 450 nm (2.755 eV), respectively.…”

Section: Resultssupporting

confidence: 84%

“…In the past, we have reported on the growth as well as on structural and optical characterization of InGaN MQW structures with partial reduction of the polarization mismatch by use of quaternary AlInGaN barriers . Our experiments employing continuous layer growth indicated at low growth rates a possibly higher stability of highly lattice‐mismatched AlInGaN layers against lattice relaxation, a key requirement for the realization of polarization‐field reduced InGaN/AlInGaN QWs emitting in the green spectral region.…”

Section: Introductionmentioning

confidence: 95%

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Polarization engineering of c‐plane InGaN quantum wells by pulsed‐flow growth of AlInGaN barriers

Neugebauer

Metzner

Bläsing

et al. 2015

Physica Status Solidi (b)

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Polarization‐field reduction in c‐plane InGaN multi‐quantum well (MQW) structures is achieved by pulsed‐flow growth of quaternary AlInGaN barriers using metalorganic vapor phase epitaxy (MOVPE). The pulsed‐flow growth allows for precise control of the quaternary composition at very low growth rate. In photoluminescence (PL) experiments a blue‐shift of the MQW emission wavelength is observed by successive adjustment of the AlInGaN barriers toward reduced polarization mismatch to the InGaN quantum wells. Accordingly, we find a decreasing radiative lifetime by time resolved cathodoluminescence (TRCL). The application of AlInGaN as barrier material instead of conventional GaN is limited by plastic relaxation. While for InGaN‐QWs emitting in the violet‐blue spectral region, fully polarization‐matched AlInGaN barriers can be realized, for long‐wavelength (green spectral region) severe lattice relaxation is observed leading to inferior optical properties as compared to binary GaN barriers.

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Section: Resultssupporting

confidence: 84%

Section: Introductionmentioning

confidence: 95%

Polarization engineering of c‐plane InGaN quantum wells by pulsed‐flow growth of AlInGaN barriers

Neugebauer

Metzner

Bläsing

et al. 2015

Physica Status Solidi (b)

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“…This inherent effect, which was called quantum-confined stark effect (QCSE), has resulted in the reduction of quantum efficiency for the GaN-based LEDs. This is because the QCSE within MQWs region lead to the significant spatial separation of the electron and hole wave functions and the reduction of the electron-hole recombination probability [1][2][3][4][5]. Furthermore, investigating the spontaneous and piezoelectric polarization-induced electrostatic field on InGaN/GaN MQWs heterostructure is a very important key issue currently.…”

Section: Introductionmentioning

confidence: 99%

Investigating the Effect of Piezoelectric Polarization on GaN-Based LEDs with Different Prestrain Layer by Temperature-Dependent Electroluminescence

Wang

Chiou²,

Chiang³

et al. 2015

International Journal of Photoenergy

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The effect of piezoelectric polarization on GaN-based light emitting diodes (LEDs) with different kinds of prestrain layers between the multiple quantum wells (MQWs) and n-GaN layer is studied and demonstrated. Compared with the conventional LED, more than 10% enhancement in the output power of the LED with prestrain layer can be attributed to the reduction of polarization field within MQWs region. In this study, we reported a simple method to provide useful comparison of polarization fields within active region in GaN-based LEDs by using temperature-dependent electroluminescence (EL) measurement. The results pointed out that the polarization field of conventional LED was stronger than that of the others due to larger variation of the wavelength transition position (i.e., blue-shift change to red-shift) from 300 to 350 K, and thus the larger polarization field must be effectively screened by injecting more carriers into the MQWs region.

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“…A recent report indicated that, with increasing indium content in the AlGaInN barriers, an increasing pit and defect density is observed, and more lattice relaxation is determined [22]. Although the technology in growing AlGaInN films is still under development, some approaches regarding the polarization-matched active region have been achieved in experiments, which demonstrates its possibility for future applications [22,23]. Note that other approaches, such as reducing GaN barrier thickness and growing semipolar or nonpolar LEDs, might also be of great help in solving the problem of efficiency droop [24][25][26].…”

mentioning

confidence: 98%

“…The increased strain accumulation in the active region makes it a great challenge to grow high-crystalline-quality devices. A recent report indicated that, with increasing indium content in the AlGaInN barriers, an increasing pit and defect density is observed, and more lattice relaxation is determined [22]. Although the technology in growing AlGaInN films is still under development, some approaches regarding the polarization-matched active region have been achieved in experiments, which demonstrates its possibility for future applications [22,23].…”

mentioning

confidence: 99%

Numerical study of the suppressed efficiency droop in blue InGaN LEDs with polarization-matched configuration

et al. 2013

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In blue InGaN light-emitting diodes (LEDs), the intuitive approaches to suppress Auger recombination by reducing carrier density, e.g., increasing the number of quantum wells (QWs) and thickening the width of wells, suffer from nonuniform carrier distribution and more severe spatial separation of electron and hole wave functions. To resolve this issue, LED structures with thick InGaN wells and polarization-matched AlGaInN barriers are proposed theoretically. Furthermore, the number of QWs is reduced for the purpose of mitigating the additional compressive strain in AlGaInN barriers. Simulation results reveal that, in the proposed structures, the quantum-confined Stark effect in strained wells is nearly eliminated through the utilization of polarization-matched barriers, which efficiently promotes internal quantum efficiency. Furthermore, the phenomenon of efficiency droop is also markedly improved because of the uniformly distributed or dispersed carriers, and accordingly the suppressed Auger recombination.

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Green to blue polarization compensated c-axis oriented multi-quantum wells by AlGaInN barrier layers

Cited by 14 publications

References 16 publications

Polarization engineering of c‐plane InGaN quantum wells by pulsed‐flow growth of AlInGaN barriers

Polarization engineering of c‐plane InGaN quantum wells by pulsed‐flow growth of AlInGaN barriers

Investigating the Effect of Piezoelectric Polarization on GaN-Based LEDs with Different Prestrain Layer by Temperature-Dependent Electroluminescence

Numerical study of the suppressed efficiency droop in blue InGaN LEDs with polarization-matched configuration

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