Spectral response measurements of multijunction solar cells with low shunt resistance and breakdown voltages

Babaro, Juan Pablo; West, Keld; Hamadani, Behrang H.

doi:10.1002/ese3.141

Cited by 15 publications

(5 citation statements)

References 27 publications

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“…Firstly, the Ge sub-cell with bandgap of 0.67 eV is not a suitable bottom candidate, which absorbs two times more photons than the top two junctions do [Friedman and Olson, 2001]. Secondly, the GaInP top cell with bandgap of 1.9 eV can only absorb the specific spectrum lower than 670 nm [Babaro et al, 2016]. Consequently, the present currentmismatched MTJ-SCs haven't reach the expected efficiency of the current matching models [Mellor et al, 2017].…”

Section: Introductionmentioning

confidence: 94%

“…As can be seen, the theoretical surface plasmon resonance peaks for Au decahedra, sphere and ellipsoid NPs are 547, 497 and 520 nm, respectively. The experimental counterpart of Au decahedra NPs is 546 nm too, and the increased extinction ability almost disappears for wavelength beyond 600 nm, which indicates that Au decahedra NPs only can boost the optical absorption enhancement of GaInP top-cell with the absorption edge of 670 nm [Babaro et al, 2016]. From the results obtained up till now, both the plasmonic peak and intensity of Au decahedral desire a better light trapping performance as contrast to the sphere and ellipsoid NPs, and thus foretelling a distinct photocurrent enhancement of SCs.…”

Section: Morphology and Optical Properties Of Au Decahedral Npsmentioning

confidence: 99%

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Boosting photocurrent of GaInP top-cell for current-matched III–V monolithic multiple-junction solar cells via plasmonic decahedral-shaped Au nanoparticles

et al. 2018

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Unbalanced photocurrent output for each sub-cell in monolithic multiple junction solar cells (MMJ-SCs) reduces the achievable photovoltaic power efficiency (PCE). Here, we first introduce Au decahedra nanoparticles to realize the plasmon-enhanced photo-absorption of GaInP top-cell and achieve the current-matched MMJ-SCs. By simply spin-coating the Au decahedral nanoparticles on the illuminated surface of the devices, the PCEs of the monolithic double junction and triple junction solar cells increase significantly from 27.01% to 28.63% and from 29.88% to 31.90%, respectively. Both the theoretical local electromagnetic distributions and the experimental extinction properties confirm the plasmonic induced absorption enhancement in device performance, and further elucidate the essential reason for photocurrent enhancement derives from the more furious oscillation of free electrons in the vicinity of sharp vertexes for Au decahedra nanoparticles. Our results demonstrate that Au decahedra with sharp vertexes and edges are promising for meliorating the trade-off between light absorption and carrier collection in GaInP top-cell. In addition, this facile and simple strategy also highlights non-annealing treatment and prevents the impurity diffusion at high temperature for MMJ-SCs, and may facilitate other types of solarharvesting devices.

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Section: Introductionmentioning

confidence: 94%

Section: Morphology and Optical Properties Of Au Decahedral Npsmentioning

confidence: 99%

Boosting photocurrent of GaInP top-cell for current-matched III–V monolithic multiple-junction solar cells via plasmonic decahedral-shaped Au nanoparticles

et al. 2018

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“…Non‐normalized data are depicted in Figures S2 and S3 (Supporting Information). Note that the Ge subcell EQE has been corrected from typical measurement artifacts that arise from low shunt resistances and low breakdown voltages prior to normalization following literature procedures, [ 44,45 ] as detailed in the Supporting Information.…”

Section: Proton Radiation Hardness Of Perovskite 2j Tandem Photovoltaicsmentioning

confidence: 99%

Proton‐Radiation Tolerant All‐Perovskite Multijunction Solar Cells

Lang

Eperon

Frohna

et al. 2021

Advanced Energy Materials

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Radiation‐resistant but cost‐efficient, flexible, and ultralight solar sheets with high specific power (W g−1) are the “holy grail” of the new space revolution, powering private space exploration, low‐cost missions, and future habitats on Moon and Mars. Herein, this study investigates an all‐perovskite tandem photovoltaic (PV) technology that uses an ultrathin active layer (1.56 µm) but offers high power conversion efficiency, and discusses its potential for high‐specific‐power applications. This study demonstrates that all‐perovskite tandems possess a high tolerance to the harsh radiation environment in space. The tests under 68 MeV proton irradiation show negligible degradation (<6%) at a dose of 1013 p+ cm−2 where even commercially available radiation‐hardened space PV degrade >22%. Using high spatial resolution photoluminescence (PL) microscopy, it is revealed that defect clusters in GaAs are responsible for the degradation of current space‐PV. By contrast, negligible reduction in PL of the individual perovskite subcells even after the highest dose studied is observed. Studying the intensity‐dependent PL of bare low‐gap and high‐gap perovskite absorbers, it is shown that the VOC, fill factor, and efficiency potentials remain identically high after irradiation. Radiation damage of all‐perovskite tandems thus has a fundamentally different origin to traditional space PV.

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“…A suite of opto-electronic characterization techniques has been used in the past to explore the various characteristics of these cells. Extensive light bias and voltage bias dependent external quantum efficiency measurements [3–10], detailed current-voltage (I–V) characterization [11], and electroluminescence measurements [12,13] have traditionally been used to elucidate various artifacts and phenomena such as low shunt resistance effects [3,6,7,9,14,15], reverse breakdown voltage [3,4,16], and luminescence coupling (LC) [10,11,17–21] in these devices. Furthermore, new techniques such as electric modulus spectroscopy [22] have been used to observe charge coupling effects in Ge-based triple junction solar cells.…”

Section: Introductionmentioning

confidence: 99%

Frequency response of the external quantum efficiency in multijunction solar cells

Peraca¹,

Bilir²,

Hamadani³

2017

Opt. Express

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The frequency dependence of the external quantum efficiency (EQE) of high-quality multijunction solar cells was examined by the modulated photocurrent spectroscopy method via an optical setup comprised of a light-pipe-coupled compact LED array. The optical excitation was achieved through sinusoidal electrical modulation of an appropriate LED by a custom-designed, high bandwidth amplifier. We observed unique features in the amplitude and phase data of the EQE frequency sweeps that are very sensitive to various subcell parameters and light bias conditions. These features are discussed extensively within the context of an AC equivalent circuit model, showing remarkable agreement between the experimental data and the proposed model.

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Spectral response measurements of multijunction solar cells with low shunt resistance and breakdown voltages

Cited by 15 publications

References 27 publications

Boosting photocurrent of GaInP top-cell for current-matched III–V monolithic multiple-junction solar cells via plasmonic decahedral-shaped Au nanoparticles

Boosting photocurrent of GaInP top-cell for current-matched III–V monolithic multiple-junction solar cells via plasmonic decahedral-shaped Au nanoparticles

Proton‐Radiation Tolerant All‐Perovskite Multijunction Solar Cells

Frequency response of the external quantum efficiency in multijunction solar cells

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