Nonradiative centers in deep‐UV AlGaN‐based quantum wells revealed by two‐wavelength excited photoluminescence

Kamata, Norihiko; Islam, A. Z. M. Touhidul; Julkarnain, M.; Murakoshi, N.; Fukuda, Tsuguo; Hasegawa, Hideki

doi:10.1002/pssb.201451582

Cited by 11 publications

(11 citation statements)

References 20 publications

(29 reference statements)

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“…The BGE energy dependence gives us a direct clue for determining the origins and improving the growth condition. An incorporation of small amount In is effective for improving the internal quantum efficiency, but quite sensitive to the growth temperature [25]. These results are to be discussed with previous reports on deep levels in AlGaN as a function of Al composition [33][34][35].…”

Section: Spatial and Energy Distribution In Ingan Mqwsupporting

confidence: 63%

“…Therefore any increase or decrease of the PL intensity due to the addition of the BGE implies a sign of NRR centers which can be interpreted by either one level model or two levels model at their simplest form. Measurements of GaAs-based quantum wells (QWs) [11][12][13][14][15][16][17][18][19][20][21], GaN/InGaN-QWs [19][20][21][22][23], AlGaN-QWs for deep UV wavelength region [24][25], GaPN [26][27] and Ba 3 Si 6 O 12 N 2 : Eu 2+ phosphors [28] have been done by such straightforward experimental principle.…”

Section: Study By Below-gap Excitationmentioning

confidence: 99%

See 1 more Smart Citation

Photoluminescence Characterization of Nonradiative Recombination Centers in Light Emitting Materials by Utilizing Below-Gap Excitation: A Mini Review of Two-Wavelength Excited Photoluminescence

Kamata

Islam

2015

Rajshahi Univ. j. sci. eng.

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We have developed an optical method of detecting and characterizing nonradiative recombination (NRR) centers without electrical contact. The method combines a belowgap excitation (BGE) light with a conventional above-gap excitation light in photoluminescence (PL) measurement, and discriminates the PL intensity change due to switching on and off the BGE. A quantitative analysis of the detected NRR centers became possible by utilizing the saturating tendency of the PL intensity change with increasing the BGE density due to trap filling effect. Some experimental results of AlGaAs, InGaN, and AlGaN quantum wells were shown to allocate the development and present status as well as to exemplify their interpretations.Keywords: Internal quantum efficiency; photoluminescence; nonradiative recombination; below-gap excitation; defect states. INTRODUCTIONLight emitting diodes (LEDs) and laser diodes (LDs) in near infrared region realized fiber communication systems in 1970's [1] and provided an infrastructure of the world wide web of huge digital data link. The realization of blue and green LEDs through steady efforts on crystal growth technique of GaN [2-3] opened another revolution in lighting and display applications since three primary colors have been provided by efficient solid state light sources. Light-based science and technology are becoming more and more important for human society as vast information comes from our sense of sight.

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Section: Spatial and Energy Distribution In Ingan Mqwsupporting

confidence: 63%

Section: Study By Below-gap Excitationmentioning

confidence: 99%

Photoluminescence Characterization of Nonradiative Recombination Centers in Light Emitting Materials by Utilizing Below-Gap Excitation: A Mini Review of Two-Wavelength Excited Photoluminescence

Kamata

Islam

2015

Rajshahi Univ. j. sci. eng.

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“…Besides threading dislocations (TDs), the impurity (such as oxygen) effect is greater in AlN epitaxial layers than in GaN due to low diffusion length of Al atoms (high sticking coefficient) and increased affinity of Al to oxidize, which cause rather high density of defects in AlGaN layers with Al content larger than 50% [6,7]. Unlike the defects in InGaN/GaN MQWs which have been widely studied (even though the influence of defects on emission efficiency is still controversial) [8][9][10][11][12][13], only a few reports have focused on the study of the typical defects in metal organic vapor phase epitaxy (MOVPE) grown AlGaN MQWs on AlN templates for DUV devices and especially their influences on the optical emission [14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Structural and optical investigations of AlGaN MQWs grown on a relaxed AlGaN buffer on AlN templates for emission at 280nm

Gac

Bouchoule³

et al. 2015

Journal of Crystal Growth

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“…In previous work, with temperature-dependent properties, we used temperature-controlled metal cryostat for TWEPL measurement. [37,38,40,[50][51][52][53][54] Based on these studies, we prepared a glass cryostat for the TWEPL measurement in which the sample was immersed in liquid nitrogen (N 2 ) directly to avoid surface temperature effect. Two different light sources of AGE, a THG Nd:YAG laser with hν A1 ¼ 3.49 eV (355 nm wavelength) and a semiconductor laser with hν A2 ¼ 2.33 eV (532 nm), were used as CB excitation and IB excitation, respectively.…”

Section: Methodsmentioning

confidence: 99%

Detection of Nonradiative Recombination Centers in GaPN by Combining Two‐Wavelength Excited Photoluminescence and Time‐Resolved Photoluminescence

Ferdous

Iwai

Kamata

et al. 2021

Physica Status Solidi (b)

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Presence and influence of nonradiative recombination (NRR) centers in an intermediate band (IB)‐type material, GaP1–xNx (x=0.75%), are studied by two‐wavelength excited photoluminescence (TWEPL) method and time‐resolved photoluminescence (TRPL) measurement at 77 K. With the use of below‐gap excitation (BGE) light in addition to an above‐gap excitation (AGE), the PL peak intensity is found to increase which indicates the presence of NRR centers and a secondary excitation from the IB to conduction band (CB). Depending on the effect of different BGE energies, an energy diagram on the distribution of NRR centers and NRR process is interpreted. The saturation of PL increase is attributed to the trap‐filling effect in NRR centers, which allows us to modify the rate equation. The NRR parameters are evaluated by a qualitative simulation of the modified rate equations of one‐level model together with the lifetime determined by TRPL. In continuation of evaluating NRR parameters by rate equation analysis, the addition of TRPL measurement improves accuracy and approaches the determination of NRR parameters. A successful characterization of NRR centers leads to a proper optimization of IB‐type solar cells (IBSCs).

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Nonradiative centers in deep‐UV AlGaN‐based quantum wells revealed by two‐wavelength excited photoluminescence

Cited by 11 publications

References 20 publications

Photoluminescence Characterization of Nonradiative Recombination Centers in Light Emitting Materials by Utilizing Below-Gap Excitation: A Mini Review of Two-Wavelength Excited Photoluminescence

Photoluminescence Characterization of Nonradiative Recombination Centers in Light Emitting Materials by Utilizing Below-Gap Excitation: A Mini Review of Two-Wavelength Excited Photoluminescence

Structural and optical investigations of AlGaN MQWs grown on a relaxed AlGaN buffer on AlN templates for emission at 280nm

Detection of Nonradiative Recombination Centers in GaPN by Combining Two‐Wavelength Excited Photoluminescence and Time‐Resolved Photoluminescence

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