Bandgap Assessment of Compositional Variation for Uncovering High‐Efficiency Improved Stable All‐Inorganic Lead‐Free Perovskite Solar Cells

Prabu, R. Thandaiah; Malathi, S R; Kumar, Atul; Al‐Asbahi, Bandar Ali; Laref, A.

doi:10.1002/pssa.202200791

Cited by 29 publications

(4 citation statements)

References 80 publications

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“…[5] The rapid and spontaneous oxidation of Sn 2þ to Sn 4þ during crystallization releases holes in the valence band, leading to strong p-type doping and destabilizing the device's p-i-n configuration. [6][7][8][9][10][11] Recent literature reports suggested that substituting Pb 2þ with mixed Ge-Sn could effectively solve the lead toxicity issue on the one hand and the long-term stability on the other. [12][13][14][15] This mixed Sn-Ge cation at the B site in ABX 3 perovskite has improved ambient, thermal, and photostability while preserving excellent photophysical and wide-bandgap tunability properties of perovskite.The peculiar, enhanced stability of tinÀgermanium Sn-Ge alloyed perovskite such as CsSn 0.5 Ge 0.5 I 3 is due to the introduction of Ge.…”

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confidence: 99%

CsSn_0.5Ge_0.5I₃‐Based Lead‐Free Highly Stable Perovskite Solar Cell: Numerical Modeling for Estimating Performance Ceiling

Sujith,

Prabu,

et al. 2023

Physica Status Solidi (a)

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CsSn0.5Ge0.5I3 perovskite is reportedly highly stable in ambient open‐air, lead‐free, and has excellent optoelectrical properties. We simulated an inverted p‐i‐n solar cell device based on this mixed SnGe perovskite utilizing the reported optical and electrical characteristics of the CsSn0.5Ge0.5I3. We put this theoretical device under various recombination regimes to explore the performance ceiling of the CsSn0.5Ge0.5I3. An optimized configuration of CsSn0.5Ge0.5I3‐based perovskite solar cell showed an efficiency of 29% under the impact of only intrinsic recombination losses such as radiative (with radiative recombination coefficient of 10‐11) and Auger recombination (recombination coefficient of 10‐27). When extrinsic factors are considered, such as resistance losses (series resistance as high as 2 Ωcm2 and shunt resistance as low as 1000 Ωcm2), efficiency decreases to 27.5%. The efficiency is 20% when trap‐assisted Schockey Read Hall SRH recombination are considered with voltage loss (VLoss) of 0.5V. Similarly, VLoss = 0.6V in VOC restricts device efficiency to 15%. Finally, an efficiency waterfall chart summarized the CsSn0.5Ge0.5I3, efficiency under different extrinsic losses, and the performance loss analysis, providing an optimal design. The results summarized here are expected to be helpful and prompt experimentalists to fabricate this stable lead‐free perovskite solar cell.This article is protected by copyright. All rights reserved.

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confidence: 99%

CsSn_0.5Ge_0.5I₃‐Based Lead‐Free Highly Stable Perovskite Solar Cell: Numerical Modeling for Estimating Performance Ceiling

Sujith,

Prabu,

et al. 2023

Physica Status Solidi (a)

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“…R S should remain below 1 Ω cm 2, and R Sh must be above 1 k Ωcm 2 for efficient device functioning. The empirical relation gives the dependence of device J – V characteristic on R S and R Sh [ 24 ]

I = I_{\text{ph}} - I_{\text{s}} \left(\right. e^{\frac{q V + I R_{\text{s}}}{n k T}} - 1 \left.\right) - \frac{V + I R_{\text{s}}}{R_{\text{Sh}}}

V is the applied voltage, I ph is the light generated current, I s , n , K , and T are the reverse saturation current, ideality factor, Boltzmann constant, and temperature, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…[16] SCAPS is a 1D Poisson solver package for simulating solar devices, available from the University of Gent, Belgium, Department of Electronics and Information Systems (ELIS), by Marc Burgelman et al [17] SCAPS-1D results have good coherence between experimental and simulation results with an error margin of less than 10 À15 . [18] It can model thin-film polycrystalline solar cells like CdTe, [19] CIGS, [20] CZTS, [21] SnS, [22] FeS 2 , [23] perovskite [24,25] etc. SCAPS solves three basic differential semiconductor equations (Poisson equation and continuity equation for both holes and electrons) at the interface/contact of the device structure.…”

Section: Simulation Methodologymentioning

confidence: 99%

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Simulation of Native Oxide‐Passivated CsSn_0.5Ge_0.5I₃ Highly Stable Lead‐Free Inorganic Perovskite Solar Cell

Livingston¹,

Prabu

Radhika³

et al. 2023

Physica Status Solidi (a)

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The rapid evolution of efficiency from 3% in 2009 to 25% today [1,2] has made perovskite a potential alternative to costly Si and GaAs photovoltaic material. The remarkable optical absorption properties, wide-bandgap tunability, high diffusion length, defects tolerance, and solution-based benign fabrication have made perovskite a significant photovoltaic (PV) material. However, on the other hand, Pb presence and phase stability are concerning challenges associated with perovskite. [3] Replacing Pb with the same group smaller element, Sn is seen in MASnX 3 , FASnX 3 , and inorganic CsSnX 3 . The performance of MASnI3 is 7.1%, [2] and FA-based SnX 3 is about 14.3%; [4] similarly, the CsSnX 3 have crossed 10%. [5] Sn replacement might have solved the Pb toxicity issue but it is still plagued with stability issues. The rapid oxidation of Sn þ2 to Sn þ4 is an unresolved issue in high-efficiency CsSnI 3 perovskites. [6] It is consistently reported in the literature that the Sn readily goes under oxidation from Sn þ2 to Sn þ4 , which rapidly degrades and further aggravates the stability issues of Sn-based perovskite. [6] Group 14 elements of Pb, Sn, Cd, and Ge all form narrow-bandgap perovskite; among these, only Ge fulfils the criteria of Earth abundance and nontoxicity. Some reports in the literature exist about the partial substitution of Ge in Snbased perovskites, such as MASnGeI 3 , CsSnGeI 3 etc. The mixed inorganic perovskite, thus resulting out of Sn-Ge systems, has demonstrated higher stability than Sn alone at the B site in perovskite. [7] Ge, Sn, and Pb have increasing ionic radii and similar electronic configurations with ns 2 lone pair whose activity increases with reducing ion size. The probability of a hole appearing in the valence band is higher in the Sn/Ge-based perovskite than in the Pb-based perovskite. The hybridization of the 5s and 4s bands of Sn and Ge with the 5p state of halide in the valance band causes the generation of holes. [8] Pure Ge-based perovskites such as MAGeI 3 and CsGeI 3 have exhibited remarkably high ionic conductivity and similar optical properties as MAPbI 3 with high absorption and weak reflectance. [9,10] The imaginary part of the dielectric function and absorption coefficient show a blueshift in Ge-based perovskite compared to Pb-based perovskite, implying the strong absorption of the visible region in Ge perovskite. [11] The negative free energy of formation for MAGeI 3 is similar to MAPbI 3 , suggesting similar stability of the two perovskite phases. The order of the stability of Pb-, Sn-, Ge-based perovskite is summarized as MAPbI 3 > MAGeI 3 > MASnI 3 > MAGeCl 3 >MAGeBr 3 by Rossella et al. and [6] Sun et al., [9] where the stability of MAGeI 3 is comparable with MAPbI 3 . Ge is lighter when compared with both Pb and Sn, enabling Ge-based perovskite to have higher power density than later. [7] The stability order for Cs-based perovskite (CsGeI 3 ) is CsSn 0.5 Ge 0.5 I 3 > CsSnI 3. The CsSn x Ge 1-x I 3 perovskite becomes relatively stable due to forming a Ge-rich, 5 nm-...

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Performance analysis of CsPbI3-based solar cells under light emitting diode illumination as an energy harvester for IoT and indoor photovoltaics

Sujith,

Prabu,

Kumar

et al. 2024

J Comput Electron

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Bandgap Assessment of Compositional Variation for Uncovering High‐Efficiency Improved Stable All‐Inorganic Lead‐Free Perovskite Solar Cells

Cited by 29 publications

References 80 publications

CsSn_0.5Ge_0.5I₃‐Based Lead‐Free Highly Stable Perovskite Solar Cell: Numerical Modeling for Estimating Performance Ceiling

CsSn_0.5Ge_0.5I₃‐Based Lead‐Free Highly Stable Perovskite Solar Cell: Numerical Modeling for Estimating Performance Ceiling

Simulation of Native Oxide‐Passivated CsSn_0.5Ge_0.5I₃ Highly Stable Lead‐Free Inorganic Perovskite Solar Cell

Performance analysis of CsPbI3-based solar cells under light emitting diode illumination as an energy harvester for IoT and indoor photovoltaics

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Bandgap Assessment of Compositional Variation for Uncovering High‐Efficiency Improved Stable All‐Inorganic Lead‐Free Perovskite Solar Cells

Cited by 29 publications

References 80 publications

CsSn0.5Ge0.5I3‐Based Lead‐Free Highly Stable Perovskite Solar Cell: Numerical Modeling for Estimating Performance Ceiling

CsSn0.5Ge0.5I3‐Based Lead‐Free Highly Stable Perovskite Solar Cell: Numerical Modeling for Estimating Performance Ceiling

Simulation of Native Oxide‐Passivated CsSn0.5Ge0.5I3 Highly Stable Lead‐Free Inorganic Perovskite Solar Cell

Performance analysis of CsPbI3-based solar cells under light emitting diode illumination as an energy harvester for IoT and indoor photovoltaics

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CsSn_0.5Ge_0.5I₃‐Based Lead‐Free Highly Stable Perovskite Solar Cell: Numerical Modeling for Estimating Performance Ceiling

CsSn_0.5Ge_0.5I₃‐Based Lead‐Free Highly Stable Perovskite Solar Cell: Numerical Modeling for Estimating Performance Ceiling

Simulation of Native Oxide‐Passivated CsSn_0.5Ge_0.5I₃ Highly Stable Lead‐Free Inorganic Perovskite Solar Cell