Adiabatic two-step photoexcitation effects in intermediate-band solar cells with quantum dot-in-well structure

Asahi, Shigeo; Kaizu, Toshiyuki

doi:10.1038/s41598-019-44335-8

Cited by 12 publications

(10 citation statements)

References 36 publications

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“…It is noted that the nonradiative component is overestimated because we do not take into account the weak PL from the InAs wetting layer and the GaAs in our analysis. Within the accuracy of our assumptions, we find that 7% of the photogenerated carriers in the GaAs are collected via TPU in our device at −0.6 V. As J p is generated by adiabatic excitation in the TPU process, it is expected that the output voltage will be boosted [36]. Figure 5(c) compares the voltage increase V that is induced by the TPU process and the IR-induced J p as a function of the bias voltage.…”

Section: Evaluation Of Absolute Carrier Collection Efficiencymentioning

confidence: 53%

Reciprocal Relation Between Intraband Carrier Generation and Interband Recombination at the Heterointerface of Two-Step Photon Up-Conversion Solar Cells

Kinugawa

Asahi

2020

Phys. Rev. Applied

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Photon up-conversion processes are considered beneficial for energy-conversion devices. The recently proposed two-step photon up-conversion (TPU) solar-cell design employs an intermediate level with a high electron occupation probability. To understand the device physics, a quantitative evaluation of the different current-generation and loss mechanisms is required. In the present work, we use a TPU solar cell containing an InAs/GaAs quantum-dot layer located 10 nm in front of an Al 0.3 Ga 0.7 As/GaAs heterointerface. We study the relation between the photocurrent (PC), radiative recombination, and nonradiative recombination as a function of the bias voltage. The radiative interband recombination is evaluated by integrating the photoluminescence (PL) over the range from 1000 to 1300 nm. The magnitudes of the PC and PL signals generated via interband excitation of the GaAs layer depend on the bias voltage; a higher forward bias reduces the PC and increases the PL intensity. We verify that, under additional infrared light illumination at 1319 nm, which induces intraband transitions, the PC density increases while the PL intensity significantly decreases. This PC enhancement exhibits a maximum at −0.6 V, which reflects the optimum internal electric field strength for maximizing the TPU efficiency.

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Section: Evaluation Of Absolute Carrier Collection Efficiencymentioning

confidence: 53%

Reciprocal Relation Between Intraband Carrier Generation and Interband Recombination at the Heterointerface of Two-Step Photon Up-Conversion Solar Cells

Kinugawa

Asahi

2020

Phys. Rev. Applied

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“…While room temperature two-photon photocurrent (TPP) results have been reported previously, [4][5][6][7][18][19][20][21] they were measured with steady state illumination schemes whose validity has come into question due to the likelihood of thermal artefacts. [22] Here we developed a high-speed double-demodulation two-photon spectroscopy setup (see Experimental Section) to measure the TPP, and to verify that its dynamical characteristics evidenced an electronic and not a thermal origin.…”

Section: Introductionmentioning

confidence: 99%

“…[1,2] A third set of energy states is introduced between the valence band (VB) and conduction band (CB) often termed "Intermediate Band" (IB), so that electrons can be promoted from the VB to CB by the sequential two-photon absorption (STPA) of photons with energies below the bulk bandgap, in a way that generates additional photocurrent and increases the theoretical efficiency limit to 46.7% under one sun. [2] A number of physical implementations have been trialed, [3][4][5][6][7] however, the presence of the IB often leads to additional non-radiative recombination channels. [8][9][10][11][12] Vaquero-Stainer et al demonstrated the successful operation, albeit at low temperature, of a quantum ratchet IBSC (QR-IBSC) using a quantum well superlattice (QWSL).…”

Section: Introductionmentioning

confidence: 99%

Room Temperature Operation of a Quantum Ratchet Intermediate Band Solar Cell

et al. 2023

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An intermediate band solar cell which generates photocurrent due to sequential absorption of two sub‐bandgap photons at temperatures up to 300 K was realized. The intermediate band is comprised of a “quantum ratchet” semiconductor nanostructure which is designed to store the photoelectron in a long‐lived state that allows for efficient optical re‐absorption; it incorporates a potential barrier designed to both increase the confinement of electrons and reduce thermal escape. This leads to extended electron lifetimes in the ratchet state and room temperature operation. At low temperature (≈12 K), electrons exhibit a ratchet state lifetime of τRB > 100 s, representing an increase by a factor of ≈107 over a device without the barrier.

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“…13,14) By employing a more casual device design, we reported that IBSCs based on quantum dots-in-a-well (DWELL) structures can be also promising. [17][18][19][20][21] In our Al 0.3 Ga 0.7 As p-i-n single-junction SC containing GaAs/ InAs/GaAs DWELL layers, the two-step excitation process occurs via a quantum well (QW) interband transition and a following QD intraband transition. There is a ratchet-like band alignment that deeply confines the photoexcited electrons after the QW interband excitation because these electrons are expected to undergo a quick relaxation from the QW to the QD before a second photon is absorbed.…”

Section: Introductionmentioning

confidence: 99%

Diffusion photocurrent influenced by intraband excitation in an intermediate band solar cell with type-I band alignment

Zhu¹,

Asahi²,

MIYASHITA³

et al. 2022

Jpn. J. Appl. Phys.

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We elucidate a photocarrier collection mechanism in intermediate band solar cells (IBSCs) with InAs-quantum dots (QDs)-in-an-Al0.3Ga0.7As/GaAs-quantum well structures. When the Al0.3Ga0.7As barrier is excited, the device electrical output can be varied by additional infrared light for the electron intraband optical transition in QDs. The photocurrent in IBSC with a single QDs-in-a-well structure shows a monotonic increase with the intraband-excitation density. Conversely, IBSC with a multilayered QDs-in-a-well structure exhibits a photocurrent reduction when electrons in QDs are optically pumped out. The simultaneously measured photoluminescence spectra proved that the polarity of QD states changes depending on the intraband-excitation density. We discuss the drift and diffusion current components and point out that the hole diffusion current is significantly influenced by carriers inside the confinement structure. Under strong intraband excitations, we consider an increased hole diffusion current occurs by blocking hole-capture in the quantum structures. This causes unexpected photocurrent reduction in the multilayered device.

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Adiabatic two-step photoexcitation effects in intermediate-band solar cells with quantum dot-in-well structure

Cited by 12 publications

References 36 publications

Reciprocal Relation Between Intraband Carrier Generation and Interband Recombination at the Heterointerface of Two-Step Photon Up-Conversion Solar Cells

Reciprocal Relation Between Intraband Carrier Generation and Interband Recombination at the Heterointerface of Two-Step Photon Up-Conversion Solar Cells

Room Temperature Operation of a Quantum Ratchet Intermediate Band Solar Cell

Diffusion photocurrent influenced by intraband excitation in an intermediate band solar cell with type-I band alignment

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