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

Kinugawa, Noriyuki; Asahi, Shigeo

doi:10.1103/physrevapplied.14.014010

Cited by 5 publications

(5 citation statements)

References 35 publications

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“…In a previous study, we presented a reciprocal relation between intraband carrier generation and interband radiative recombination at the QDs in a heterojunction SC. 29) Similar to that work, we qualitatively examined the state filling in the QDs by measuring the PL spectra under short-circuit conditions. Figure 4(a) shows how the PL spectrum at 200 K depends on P IB-CB (other temperatures resulted in similar trends).…”

Section: Data Analysesmentioning

confidence: 94%

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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Section: Data Analysesmentioning

confidence: 94%

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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“…These accumulated electrons partially recombine with the holes that reach HI-I by diffusion. We described this scenario in previous publications [10][11][12][13] . A part of the electrons at HI-I can overcome the energy barrier by thermal excitation (evidence for thermionic emission is provided in In uence of the Temperature).…”

Section: Eqe Spectramentioning

confidence: 99%

“…In particular, in an Al 0.3 Ga 0.7 As/GaAs-based TPU-SC, there is no IR-induced EQE enhancement when the wavelength of the photons for interband excitation is shorter than 680 nm (the Al 0.3 Ga 0.7 As bandgap). This result is attributed to the fact that high-energy photons are strongly absorbed by the WGS, [10][11][12][13] which causes a reduction of the number of photons that reach the NGS layer, leading to a reduction of the electron density at the heterointerface. As a result, the IR-induced photocurrent enhancement gradually disappears as the wavelength of the photons for interband excitation becomes shorter; if there are no photogenerated electrons in the NGS CB, the IR laser beam has no effect, because the photogenerated electrons in the WGS CB do not accumulate at the energy barrier [10][11][12] .…”

Section: Eqe Spectramentioning

confidence: 99%

“…The enhancement of absorption in IBSCs is caused by a sequential excitation of electrons from the VB to the IB and from the IB to the CB using sub-bandgap photons (in addition to the direct band-to-band transitions). Because the band-to-band transitions are independent of the excitation via the IB, an IBSC is equivalent to a parallel circuit: one branch contains one diode corresponding to band-toband transitions, and the other branch contains two diodes connected in series corresponding to the sequential absorption of sub-bandgap photons via the IB [9][10][11][12][13][14] . As a result, an IBSC is not affected by current and voltage mismatches, which are problematic in the case of multi-junction solar cells 1 .…”

Section: Introductionmentioning

confidence: 99%

“…Such a trade-off relation between fabrication complexity and e ciency hinders the commercialization of IBSCs. On the other hand, we demonstrated a so-called two-step photon upconversion solar cell (TPU-SC) based on Al 0.3 Ga 0.7 As and GaAs including a single layer of InAs QDs at the heterointerface (the QDs were prepared by using the Stranski-Krastanov growth mode) [10][11][12][13] . The fabrication of such a TPU-SC is relatively simple compared to IBSCs.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Intraband Transitions at a CsPbBr3/GaAs Heterointerface in a Two-Step Photon Upconversion Solar Cell

Mahamu,

Asahi,

Kita

2024

Preprint

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Two-step photon upconversion solar cells (TPU-SCs) based on III–V semiconductors can achieve enhanced sub-bandgap photon absorption because of intraband transitions at the heterointerface. From a technological aspect, the question arose whether similar intraband transitions can be realized by using perovskite/III–V semiconductor heterointerfaces. In this article, we demonstrate a TPU-SC based on a CsPbBr3/GaAs heterointerface. Such a solar cell can ideally achieve an energy conversion efficiency of 48.5% under 1-sun illumination. This is 2.1% higher than the theoretical efficiency of an Al0.3Ga0.7As/GaAs-based TPU-SC. Experimental results of the CsPbBr3/GaAs-based TPU-SC show that both the short-circuit current JSC and the open-circuit voltage VOC increase with additional illumination of sub-bandgap photons. We analyze the excitation power dependence of JSC for different excitation conditions to discuss the mechanisms behind the enhancement. In addition, the observed voltage-boost clarifies that the JSC enhancement is caused by an adiabatic optical process at the CsPbBr3/GaAs heterointerface, where sub-bandgap photons efficiently pump the electrons accumulated at the heterointerface to the conduction band of CsPbBr3. Besides the exceptional optoelectronic properties of CsPbBr3 and GaAs, the availability of a CsPbBr3/GaAs heterointerface for two-step photon upconversion paves the way for the development of high-efficiency perovskite/III–V semiconductor-based single-junction solar cells.

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Voltage boost effects in two-step photon upconversion solar cells with a modulation-doped structure

Watanabe

Asahi

Zhu

2021

Journal of Applied Physics

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A two-step photon upconversion (TPU) solar cell is a single-junction solar cell with a suitably designed heterointerface in the intrinsic layer. At this interface, upconversion can take place by absorbing infrared light, which excites carriers to energies above the heterojunction barrier, and then an electric field extracts these upconverted carriers to the barrier material. In this work, we study this photoabsorption process in a TPU solar cell with a modulation-doped structure. The modulation doping technique enables us to control the electric field at the heterointerface, and we demonstrate that the efficiency of the TPU process strongly depends on the electric field at the heterointerface. While we show that the TPU process induced by infrared light leads to a significant increase in the external quantum efficiency, we also note that this TPU process is an adiabatic process. It is shown that the adiabatic intraband photoexcitation at the heterointerface is able to increase the open-circuit voltage even above the open-circuit voltage that we predict from the diode equation and the actual current increase. We demonstrate obvious voltage boost effects and elucidate the relationship between the current and voltage.

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

Cited by 5 publications

References 35 publications

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

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

Intraband Transitions at a CsPbBr3/GaAs Heterointerface in a Two-Step Photon Upconversion Solar Cell

Voltage boost effects in two-step photon upconversion solar cells with a modulation-doped structure

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