Investigation of Ultrafast Carrier Dynamics in InGaN/GaN‐Based Nanostructures Using Femtosecond Pump–Probe Absorption Spectroscopy

Aggarwal, Tarni; Udai, Ankit; Banerjee, Debashree; Pendem, Vikas; Chouksey, Shonal; Saha, D.; Sankaranarayanan, Sandeep; Ganguly, Swaroop; Bhattacharya, P.

doi:10.1002/pssb.202100223

Cited by 4 publications

(6 citation statements)

References 84 publications

(159 reference statements)

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“…BTB (b 4 ) and SRH (b 5 ) dominate at a very long time (∼ t 3 ), by which the residual carriers decay from the QW. It may be noted that these assignments of processes at various time scales t 1 , t 2 , and t 3 (obtained values of these time constants are given in Figure ) are in congruence with the quantum mechanically estimated time constants. − The time constant associated with the combined effect of the transitions (mostly) a 1 and (partly) b 1 is obtained by the single exponential fit to the initial carrier kinetics, where Δα reaches its peak negative value. The fit for the control sample near the initial kinetics at the InGaN band edge is shown in the inset of Figure a.…”

Section: Results and Discussionsupporting

confidence: 74%

Reduced Auger Coefficient through Efficient Carrier Capture and Improved Radiative Efficiency from the Broadband Optical Cavity: A Mechanism for Potential Droop Mitigation in InGaN/GaN LEDs

Aggarwal

Udai

Saha

et al. 2022

ACS Appl. Mater. Interfaces

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Efficiency droop at high carrier-injection regimes is a matter of concern in InGaN/GaN quantum-confined heterostructure-based light-emitting diodes (LEDs). Processes such as Shockley–Reed–Hall and Auger recombinations, electron–hole wavefunction separation from polarization charges, carrier leakage, and current crowding are identified as the primary contributors to efficiency droop. Auger recombination is a critical contributor owing to its cubic dependence on carrier density, which can not be circumvented using an advanced physical layout. Here, we demonstrate a potential solution through the positive effects from an optical cavity in suppressing the Auger recombination rate. Besides the phenomenon being fundamentally important, the advantages are technologically essential. The observations are manifested by the ultrafast transient absorption pump-probe spectroscopy performed on an InGaN/GaN-based multi-quantum well heterostructure with external DBR mirrors of varying optical confinement. The optical confinement modulates the nonlinear carrier and photon dynamics and alters the rate of dominant recombination mechanisms in the heterostructure. The carrier capture rate is observed to be increasing, and the polarization field is reducing in the presence of optical feedback. Reduced polarization increases the effective bandgap, resulting in the suppression of the Auger coefficient. Superluminescent behavior along with enhanced spectral purity in the emission spectra in presence of optical confinement is also demonstrated. The improvement is beyond the conventional Purcell effect observed for the quantum-confined systems.

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Section: Results and Discussionsupporting

confidence: 74%

Reduced Auger Coefficient through Efficient Carrier Capture and Improved Radiative Efficiency from the Broadband Optical Cavity: A Mechanism for Potential Droop Mitigation in InGaN/GaN LEDs

Aggarwal

Udai

Saha

et al. 2022

ACS Appl. Mater. Interfaces

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“…Carriers from the band-edge quickly get trapped into these states within a short span of 10-100 ps. More the number of traps faster is the trapping rate [62]. Further decay of excess carriers take place through band-to-band or excitonic radiative recombination.…”

Section: Femtosecond Transient Absorption Spectroscopymentioning

confidence: 99%

“…Further decay of excess carriers take place through band-to-band or excitonic radiative recombination. The radiative recombination lifetime of typical compound semiconductors is in the range of 0.1-100 ns [62].…”

Section: Femtosecond Transient Absorption Spectroscopymentioning

confidence: 99%

Revealing photoluminescence and nonlinear optical absorption characteristics of PbMo_0.75W_0.25O₄ single crystal for optical limiting applications

Doğan,

Karatay,

Isik

et al. 2024

Phys. Scr.

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Nonlinear absorption properties of PbMo0.75W0.25O4 single crystal fabricated by the Czochralski method were studied. The band gap energy of the crystal was determined as 3.12 eV. Urbach energy which represents the defect states inside the band gap was found to be 0.106 eV. PbMo0.75W0.25O4 single crystal has a broad photoluminescence emission band between 376 and 700 nm, with the highest emission intensity occurring at 486 nm and the lowest intensity peak at 547 nm, depending on the defect states. Femtosecond transient absorption measurements reveal that the lifetime of localized defect states is found to be higher than the 4 ns pulse duration. Open aperture (OA) Z-scan results demonstrate that the PbMo0.75W0.25O4 crystal exhibits nonlinear absorption (NA) that includes simultaneous two-photon absorption (TPA) as the dominant mechanism at the 532 nm excitations corresponding to 2.32 eV energy. NA coefficient (βeff) increased from 7.24 x 10-10 m/W to 8.81 x 10-10 m/W with increasing pump intensity. At higher intensities βeff tends to decrease with intensity increase. This decrease is an indication that saturable absorption (SA) occurred along with the TPA, called saturation of TPA. The lifetime of the defect states was measured by femtosecond transient absorption spectroscopy. Saturable absorption behavior was observed due to the long lifetime of the localized defect states. Closed aperture (CA) Z-scan trace shows the sign of a nonlinear refractive index. The optical limiting threshold of PbMo0.75W0.25O4 single crystal at the lowest intensity was determined as 3.45 mJ/cm2. Results show that the PbMo0.75W0.25O4 single crystal can be a suitable semiconductor material for optical limiting applications in the visible region.

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“…Unlike Gallium Arsenide (GaAs), GaN heterostructures with wurtzite crystal structures have polarisation fields, causing the spatial separation of electrons and holes, leading to the quantum-confined stark effect (QCSE) [11]. QCSE decreases the overlap of electron and hole wave functions, reducing the radiative efficiency and intensity of emission.…”

mentioning

confidence: 99%

“…QCSE decreases the overlap of electron and hole wave functions, reducing the radiative efficiency and intensity of emission. However, the extent of QCSE varies with time for the switching characteristics of LEDs, LDs, and PDs (such as sources or detectors in various communication systems or reading and writing elements in data storage) [11][12][13]. This necessitates time-dependent studies like pump-probe spectroscopy to understand and control this transient QCSE.…”

mentioning

confidence: 99%

Real-time observation of delayed excited-state dynamics in InGaN/GaN quantum-wells by femtosecond transient absorption spectroscopy

Udai

Ganguly²,

Bhattacharya³

et al. 2022

Nanotechnology

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This work employs Femtosecond Transient Absorption Spectroscopy to investigate the ultrafast carrier dynamics of bound states in In0.14Ga0.86N/GaN quantum wells. The ground state dynamics usually dominate these characteristics, appearing as a prominent peak in the absorption spectra. It is observed that the excited state also contributes to the overall dynamics, with its signature showing up later. The contributions of both the ground and excited states in the absorption spectra and time-resolved dynamics are decoupled in this work. The carrier density in the ground state first increases and then decays with time. The carriers populate the excited state only at a delayed time. The dynamics are studied considering the Quantum-Confined Stark Effect-induced wavelength shift in the absorption. The relevant microscopic optoelectronic processes are understood phenomenologically, and their time constants are extracted. An accurate study of these dynamics provides fundamentally essential insights into the time-resolved dynamics in quantum-confined heterostructures and can facilitate the development of efficient light sources using GaN heterostructures.

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Investigation of Ultrafast Carrier Dynamics in InGaN/GaN‐Based Nanostructures Using Femtosecond Pump–Probe Absorption Spectroscopy

Cited by 4 publications

References 84 publications

Reduced Auger Coefficient through Efficient Carrier Capture and Improved Radiative Efficiency from the Broadband Optical Cavity: A Mechanism for Potential Droop Mitigation in InGaN/GaN LEDs

Reduced Auger Coefficient through Efficient Carrier Capture and Improved Radiative Efficiency from the Broadband Optical Cavity: A Mechanism for Potential Droop Mitigation in InGaN/GaN LEDs

Revealing photoluminescence and nonlinear optical absorption characteristics of PbMo_0.75W_0.25O₄ single crystal for optical limiting applications

Real-time observation of delayed excited-state dynamics in InGaN/GaN quantum-wells by femtosecond transient absorption spectroscopy

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Investigation of Ultrafast Carrier Dynamics in InGaN/GaN‐Based Nanostructures Using Femtosecond Pump–Probe Absorption Spectroscopy

Cited by 4 publications

References 84 publications

Reduced Auger Coefficient through Efficient Carrier Capture and Improved Radiative Efficiency from the Broadband Optical Cavity: A Mechanism for Potential Droop Mitigation in InGaN/GaN LEDs

Reduced Auger Coefficient through Efficient Carrier Capture and Improved Radiative Efficiency from the Broadband Optical Cavity: A Mechanism for Potential Droop Mitigation in InGaN/GaN LEDs

Revealing photoluminescence and nonlinear optical absorption characteristics of PbMo0.75W0.25O4 single crystal for optical limiting applications

Real-time observation of delayed excited-state dynamics in InGaN/GaN quantum-wells by femtosecond transient absorption spectroscopy

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Revealing photoluminescence and nonlinear optical absorption characteristics of PbMo_0.75W_0.25O₄ single crystal for optical limiting applications