Design and optimization of InGaN superluminescent diodes

Kafar, Anna; Stanczyk, Szymon; Wiśniewski, P.; Oto, Takao; Makarowa, Irina; Targowski, G.; Suski, T.; Perlin, P.

doi:10.1002/pssa.201431741

Cited by 24 publications

(21 citation statements)

References 20 publications

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“…Group-III-Nitride-based superluminescent diodes (SLD) have received significant attention recently [13][14][15][16] owing to their unique features, which combine the advantages of both LEDs and LDs [17]. The short wavelength SLDs, have a broad spectral emission attributed to the coexistence of spontaneous and stimulated emission, known as amplified spontaneous emission (ASE) [18], making it a promising alternative for SSL-emitters.…”

Section: Introductionmentioning

confidence: 99%

High-power blue superluminescent diode for high CRI lighting and high-speed visible light communication

Alatawi¹,

Holguín‐Lerma²,

Kang³

et al. 2018

Opt. Express

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We demonstrated a high-power (474 mW) blue superluminescent diode (SLD) on c-plane GaN-substrate for speckle-free solid-state lighting (SSL), and high-speed visible light communication (VLC) link. The device, emitting at 442 nm, showed a large spectral bandwidth of 6.5 nm at an optical power of 105 mW. By integrating a YAG-phosphor-plate to the SLD, a CRI of 85.1 and CCT of 3392 K were measured, thus suitable for solid-state lighting. The SLD shows a relatively large 3-dB modulation bandwidth of >400 MHz, while a record high data rate of 1.45 Gigabit-per-second (Gbps) link has been achieved below forward-error correction (FEC) limit under non-return-to-zero on-off keying (NRZ-OOK) modulation scheme. Our results suggest that SLD is a promising alternative for simultaneous speckle-free white lighting and Gbps data communication dual functionalities.

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Section: Introductionmentioning

confidence: 99%

High-power blue superluminescent diode for high CRI lighting and high-speed visible light communication

Alatawi¹,

Holguín‐Lerma²,

Kang³

et al. 2018

Opt. Express

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“…The use of a passive absorber for suppressing lasing in a SLED is well known [9], [25], [26]. However, conventional (0001) GaN based devices differ from conventional (001) GaAs and InP based devices in that strong polarization (piezoelectric and spontaneous) effects induce strong electric fields within the QWs at zero applied bias [39].…”

Section: Broadband Gan Sledmentioning

confidence: 99%

“…Although various configurations of SLED design and cavity suppression have been proposed [9], limited work has been conducted on the practical use of absorbing section(s) in GaN SLEDs [25]. An absorbing section is electrically isolated from the light emitting section of a waveguide but is optically connected, with the absorbing section(s) ideally operated in loss.…”

mentioning

confidence: 99%

Gallium Nitride Superluminescent Light Emitting Diodes for Optical Coherence Tomography Applications

Goldberg

Boldin

Andersson

et al. 2017

IEEE J. Select. Topics Quantum Electron.

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Abstract-Optical coherence tomography (OCT) exploits the coherent properties of light to permit noninvasive and in situ imaging of biological tissues. By expanding the range of OCT light sources from the traditional telecoms wavelengths to include ∼400 nm gallium nitride (GaN) based superluminescent light emitting diodes (SLEDs) subcellular axial and lateral resolution could be achieved, provided enhanced bandwidth is also achieved. Due to the focus on high-power applications for GaN SLEDs, there has been limited work on increasing the source bandwidth. In this paper, we demonstrate for the first time a ∼400 nm GaN SLED with >10 nm bandwidth employed within an OCT system, where an axial resolution of ∼7 µm is achieved. Bespoke GaN SLEDs suggest that <4 µm axial resolution imaging is imminent for short wavelength devices.Index Terms-Axial resolution, broad bandwidth, gallium nitride superluminescent light emitting diodes, optical coherence tomography.

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“…Table 1 summarizes the design and performance of the demonstrated GaN-based SLDs, comparing the emission wavelength, substrate material, configuration, waveguide design, and the maximum light output power reported in each case. 405 nm c-GaN "j-shape" waveguide curved ridge 350 mW (cw) [24] 408 nm c-GaN "j-shape" waveguide "j-shape" ridge 200 mW (cw) [25] 410 ~ 445 nm c-GaN tilted waveguide 2 µm ridge 30 ~ 55 mW (cw) [26] 420 nm c-GaN tilted facet 2 µm ridge 2 mW (cw) 100 mW (pulse) [27] 420 nm c-GaN "j-shape" waveguide AR/HR coating 3 µm ridge 200 mW (cw) [28] 439 nm m-GaN facet roughening 4 µm ridge 5 mW (pulse) [29] 443 nm c-GaN curved waveguide 2 µm ridge 100 mW (cw) [30] 445 nm c-GaN oblique facet 5 µm ridge - [31] 447 nm Semipolar GaN passive absorber 7.5 µm ridge 256 mW (cw) [17] 500 nm c-GaN curved waveguide 2 µm ridge 4 mW (pulse) [32] Since most of InGaN/GaN QW SLDs are grown on a polar, c-plane GaN substrate, there is a growing interest to develop high efficient violet-blue SLDs on nonpolar or semipolar substrates owing to a reduced polarization field presented in the QW structure [2]. Studies on semipolar and nonpolar GaN-based LEDs and LDs have revealed that the enhanced electron and hole wavefunction overlap is expected for InGaN/GaN QWs grown on nonpolar (m-plane) and semipolar GaN substrates, leading to an enhanced internal quantum efficiency [2,3].…”

Section: Introductionmentioning

confidence: 99%

Semipolar InGaN-based superluminescent diodes for solid-state lighting and visible light communications

Shen

Lee

et al. 2017

SPIE Proceedings

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III-nitride light emitters, such as light-emitting diodes (LEDs) and laser diodes (LDs), have been demonstrated and studied for solid-state lighting (SSL) and visible-light communication (VLC) applications. However, for III-nitride LEDbased SSL-VLC system, its efficiency is limited by the "efficiency droop" effect and the high-speed performance is limited by a relatively small -3 dB modulation bandwidth (<100 MHz). InGaN-based LDs were recently studied as a droop-free, high-speed emitter; yet it is associated with speckle-noise and safety concerns. In this paper, we presented the semipolar InGaN-based violet-blue emitting superluminescent diodes (SLDs) as a high-brightness and high-speed light source, combining the advantages of LEDs and LDs. Utilizing the integrated passive absorber configuration, an InGaN/GaN quantum well (QW) based SLD was fabricated on semipolar GaN substrate. Using SLD to excite a YAG:Ce phosphor, white light can be generated, exhibiting a color rendering index of 68.9 and a color temperature of 4340 K. Besides, the opto-electrical properties of the SLD, the emission pattern of the phosphor-converted white light, and the high-speed (Gb/s) visible light communication link using SLD as the transmitter have been presented and discussed in this paper.

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Design and optimization of InGaN superluminescent diodes

Cited by 24 publications

References 20 publications

High-power blue superluminescent diode for high CRI lighting and high-speed visible light communication

High-power blue superluminescent diode for high CRI lighting and high-speed visible light communication

Gallium Nitride Superluminescent Light Emitting Diodes for Optical Coherence Tomography Applications

Semipolar InGaN-based superluminescent diodes for solid-state lighting and visible light communications

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