Alloying and Defect Control within Chalcogenide Perovskites for Optimized Photovoltaic Application

Meng, Weiwei; Saparov, Bayrammurad; Hong, Fung‐E; Wang, Jianbo; Mitzi, David B.; Yan, Yanfa

doi:10.1021/acs.chemmater.5b04213

Cited by 227 publications

(293 citation statements)

References 54 publications

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“…This has frequently not been implemented correctly and has led to confusion and mistakes in the past [37][38][39][40][41][42][43][44][45][46][47][48][49]. The internal and external parameters used in the scope of this work are listed in Table I as well as the equations that connect an internal parameter with its external counterpart.…”

Section: B Extended Detailed Balance Theorymentioning

confidence: 99%

“…One of the first and maybe most prominent examples of such a selection metric proposed for computational materials screening is presented by Yu and Zunger in 2012 [37] and has been widely used to estimate efficiency limits in the last years [38][39][40][41][42][43][44][45][46][47][48][49]. In their paper, they proposed a "spectroscopic limited maximum efficiency" SLME selection metric that aims to calculate efficiency limits for non-step like absorption coefficients beyond the radiative limit.…”

Section: Introductionmentioning

confidence: 99%

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Selection Metric for Photovoltaic Materials Screening Based on Detailed-Balance Analysis

et al. 2017

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The success of recently discovered absorber materials for photovoltaic applications has been generating an increasing interest in systematic materials screening over the last years. However, the key for a successful materials screening is a suitable selection metric that goes beyond the Shockley-Queisser theory that determines the thermodynamic efficiency limit of an absorber material solely by its band gap energy. In this work, we develop a selection metric to quantify the potential photovoltaic efficiency of a material. Our approach is compatible with detailed balance and applicable in computational and experimental materials screening. We use the complex refractive index to calculate radiative and nonrradiative efficiency limits and the respective optimal thickness in the high mobility limit. We compare our model to the widely applied selection metric by Yu and Zunger [Phys Rev Lett 108, 068701 (2012)] with respect to their dependency on thickness, internal luminescence quantum efficiency and refractive index. Finally the model is applied to complex refractive indices calculated via electronic structure theory.2

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Section: B Extended Detailed Balance Theorymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Selection Metric for Photovoltaic Materials Screening Based on Detailed-Balance Analysis

et al. 2017

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“…In addition, the alloy BaZr(O x S 1− x ) 3 was synthesized, and a widely tunable bandgap from 1.73 to 2.87 eV with varying S concentration was observed. Two other recent experiments have reported the bandgap of BaZrS 3 to be between 1.83 and 1.85 eV . This small discrepancy requires further experiments to resolve.…”

Section: Nonhalide Perovskitesmentioning

confidence: 84%

“…Meng et al studied the alloy and defect properties of BaZrS 3 based on DFT calculations . They investigated the alloy BaZrS 3 with Ti at the Zr sites and Se at the S sites.…”

Section: Nonhalide Perovskitesmentioning

confidence: 99%

Perovskite Solar Absorbers: Materials by Design

Yang

et al. 2018

Small Methods

101

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Solar‐cell materials with a tetrahedral diamond structure and its derived structures (i.e., zinc blende and chalcopyrite) are the most successful family of materials, with power conversion efficiencies exceeding 20%. Recent breakthroughs based on lead halide perovskites have inspired intensive research on low‐cost photovoltaics beyond diamond‐structured materials. While research has focused on addressing the key challenges faced by lead halide perovskites, that is, the stability and toxicity issues, it is of greater interest to develop perovskites into a new family of solar‐cell materials. Here, the recent efforts toward this goal are reviewed. The focus is on computational materials design, including single, double, 2D, and nonhalide perovskites and perovskite‐like materials. Meanwhile, related experiments are also reviewed with a hope that such this will help identify potential issues as well as enlightening ideas to achieve further computation‐driven materials discovery.

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“…At the same time, the advantage of accurately reproducing the target component is lost, and the deposition rate is lower. A method in which different molecular beams or atomic beams are used for directly bombarding the substrate is called molecular beam epitaxy (MBE) [33]. MBE can be used to grow films with atomic scale thickness.…”

Section: Chemical Vapor Deposition (Cvd) and (3) Chemical Bath Deposmentioning

confidence: 99%

Applications of ferroelectrics in photovoltaic devices

et al. 2016

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Ferroelectric materials exhibiting anomalous photovoltaic properties are one of the foci of photovoltaic research. We review the foundations and recent progress in ferroelectric materials for photovoltaic applications, including the physics of ferroelectricity, nature of ferroelectric thin films, characteristics and underlying mechanism of the ferroelectric photovoltaic effect, solar cells based on ferroelectric materials, and other related topics. These findings have important implications for improving the efficiency of photovoltaic cells.

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Alloying and Defect Control within Chalcogenide Perovskites for Optimized Photovoltaic Application

Cited by 227 publications

References 54 publications

Selection Metric for Photovoltaic Materials Screening Based on Detailed-Balance Analysis

Selection Metric for Photovoltaic Materials Screening Based on Detailed-Balance Analysis

Perovskite Solar Absorbers: Materials by Design

Applications of ferroelectrics in photovoltaic devices

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