Improving Light Extraction From GaN Light-Emitting Diodes by Buried Nano-Gratings

Sadi, Toufik; Oksanen, Jani; Tulkki, Jukka

doi:10.1109/jqe.2014.2299752

Cited by 14 publications

(9 citation statements)

References 24 publications

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“…The generation profiles in the PD follow the Beer-Lambert law [15]. The coupling constant is evaluated by solving the radiative transfer equation [17], with the topcontact−cap-layer system reflectivity pre-calculated using the transfer matrix method [18]. The simulations are calibrated using the three point probe I − V measurements [9], [14], biasing the LED with a voltage U and measuring the LED current I 1 , and the current generated in the PD I 2 by the LED emitted photons.…”

Section: Simulation Methods and Measurementsmentioning

confidence: 99%

Electroluminescent Cooling in III–V Intracavity Diodes: Practical Requirements

Sadi

Radevici

Kivisaari

et al. 2019

IEEE Trans. Electron Devices

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Recent studies of electroluminescent cooling in III-V structures demonstrate the need to understand better the factors affecting the efficiency of light emission and energy transport in light-emitting diodes (LEDs). In this work, we establish the physical and operational requirements for reaching the efficiencies needed for observing electroluminescent cooling in III-V intracavity double diode structures at high powers. The experimentally-validated modeling framework used in this work, coupling the drift-diffusion charge transport model with a photon transport model, indicates that the bulk properties of the III-V materials are already sufficient for electroluminescent cooling. Furthermore, the results suggest that the bulk power conversion efficiency of the LED in the devices, that allowed the experimentally measured record high coupling quantum efficiency of 70%, already exceeds 115%. However, as shown here, direct observation of electroluminescent cooling by electrical measurements still requires a combination of a more efficient suppression of the non-radiative surface recombination at the LED walls and the reduction of the detection losses in the photodetector of the intracavity structures.

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Section: Simulation Methods and Measurementsmentioning

confidence: 99%

Electroluminescent Cooling in III–V Intracavity Diodes: Practical Requirements

Sadi

Radevici

Kivisaari

et al. 2019

IEEE Trans. Electron Devices

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“…where ζ is the absorption coefficient, d is the light penetration depth, and I 0 is the intensity at reference position z = 0, matching the emission at the corresponding position in the LED. Improved photon transport models are currently being considered, such as our in-house optical model [16]− [18] to extract the reflection coefficients and Green's functions of the multi-layered structure. Ultimately, we aim to solve for the radiative transfer equation (RTE), to include more accurately photon transport along different paths and angles.…”

Section: Simulation Methodsmentioning

confidence: 99%

Electroluminescent cooling in intracavity light emitters: modeling and experiments

et al. 2017

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“…1(a), due to the lateral doping and the modified structure as indicated by the results of this work. Generally, the DDCT-LEDs can enable novel devices if the substrate is removed with e.g., an epitaxial lift-off (ELO) process [19], [20]. For example, fabrication of back-contacted TF LEDs and near surface active regions should be possible.…”

Section: Introductionmentioning

confidence: 99%

Current Spreading in Back-Contacted GaInP/GaAs Light-Emitting Diodes

Myllynen

Sadi

Oksanen

2020

IEEE Trans. Electron Devices

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The recently proposed diffusion-driven charge transport (DDCT) method can allow a paradigm shift in the design of optoelectronic devices, by changing both the current injection principle and the device structure. The DDCT injection technique is based on the bipolar electron and hole diffusion currents that are used to electrically inject charge carriers into an active region (AR) located outside the p-n junction. In this article, we study an interdigitated back-contacted DDCT-light-emitting diode (LED) based on a GaInP/GaAs double heterojunction (DHJ) structure consisting of lateral heterojunctions (LHJs) located above a uniform AR. The structure uses single-sided electrical injection and is suitable for large-area applications and thin-film devices with near-surface ARs. Our analysis, based on charge transport simulations, suggests that the structure permits more efficient current spreading and lower surface recombination than conventional structures, leading to a very high internal quantum efficiency (IQE) and injection efficiency exceeding 99%. Particularly, we investigate the implications of using the new structure for improving the efficiency of LEDs, bringing them closer to the threshold of electroluminescent cooling (ELC). The results predict an above-unity internal power conversion efficiency for the DDCT-LEDs, substantially exceeding the efficiency of conventional reference devices, highlighting the new possibilities that DDCT devices offer especially for high-power ELC at room temperature.

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Improving Light Extraction From GaN Light-Emitting Diodes by Buried Nano-Gratings

Cited by 14 publications

References 24 publications

Electroluminescent Cooling in III–V Intracavity Diodes: Practical Requirements

Electroluminescent Cooling in III–V Intracavity Diodes: Practical Requirements

Electroluminescent cooling in intracavity light emitters: modeling and experiments

Current Spreading in Back-Contacted GaInP/GaAs Light-Emitting Diodes

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