Unraveling the Native Conduction of Trichalcogenides and Its Ideal Band Alignment for New Photovoltaic Interfaces

Tumelero, Milton A.; Faccio, Ricardo; Pasa, André A.

doi:10.1021/acs.jpcc.5b10233

Cited by 64 publications

(63 citation statements)

References 66 publications

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“…Therefore, we tentatively attributed H1 and H2 defects to V Sb and Se Sb defects, respectively. As reported by Tumelero et al 44 , the antisite defects dominated the distribution of defects in trichalcogenides due to the similar sizes of the constituent atoms. Our previous simulation also showed that Se Sb and antimony antisite (Sb Se ) are acceptor and donor defects, respectively 11 .…”

Section: Resultssupporting

confidence: 62%

Vapor transport deposition of antimony selenide thin film solar cells with 7.6% efficiency

et al. 2018

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Antimony selenide is an emerging promising thin film photovoltaic material thanks to its binary composition, suitable bandgap, high absorption coefficient, inert grain boundaries and earth-abundant constituents. However, current devices produced from rapid thermal evaporation strategy suffer from low-quality film and unsatisfactory performance. Herein, we develop a vapor transport deposition technique to fabricate antimony selenide films, a technique that enables continuous and low-cost manufacturing of cadmium telluride solar cells. We improve the crystallinity of antimony selenide films and then successfully produce superstrate cadmium sulfide/antimony selenide solar cells with a certified power conversion efficiency of 7.6%, a net 2% improvement over previous 5.6% record of the same device configuration. We analyze the deep defects in antimony selenide solar cells, and find that the density of the dominant deep defects is reduced by one order of magnitude using vapor transport deposition process.

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Section: Resultssupporting

confidence: 62%

Vapor transport deposition of antimony selenide thin film solar cells with 7.6% efficiency

et al. 2018

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“…1, the literature in thermoelectric materials often shows qualitatively different results. [14][15][16][17][18] Here, we consider PbTe a well studied material with strong spin-orbit coupling, to demonstrate the challenges posed in first-principles based density functional theory (DFT) calculations aimed at bulk properties, [19][20][21][22][23][24][25] and intrinsic defects. 14,15,[26][27][28] The DFT calculations employing the local density approximation (LDA) 29 or the generalized gradient approximation (GGA) 30 for exchange correlation provide only a qualitative description of the electronic structure of PbTe.…”

Section: Introductionmentioning

confidence: 99%

First-principles calculation of intrinsic defect chemistry and self-doping in PbTe

et al. 2017

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Semiconductor dopability is inherently limited by intrinsic defect chemistry. In many thermoelectric materials, narrow band gaps due to strong spin-orbit interactions make accurate atomic level predictions of intrinsic defect chemistry and self-doping computationally challenging. Here we use different levels of theory to model point defects in PbTe, and compare and contrast the results against each other and a large body of experimental data. We find that to accurately reproduce the intrinsic defect chemistry and known self-doping behavior of PbTe, it is essential to (a) go beyond the semi-local GGA approximation to density functional theory, (b) include spin-orbit coupling, and (c) utilize many-body GW theory to describe the positions of individual band edges. The hybrid HSE functional with spin-orbit coupling included, in combination with the band edge shifts from G 0 W 0 is the only approach that accurately captures both the intrinsic conductivity type of PbTe as function of synthesis conditions as well as the measured charge carrier concentrations, without the need for experimental inputs. Our results reaffirm the critical role of the position of individual band edges in defect calculations, and demonstrate that dopability can be accurately predicted in such challenging narrow band gap materials. INTRODUCTIONThe dopability of semiconductor materials plays a decisive role in device performance. Dopability refers to the carrier concentration limits achievable in a semiconductor material. These limits are set by the compensating intrinsic (or native) defects and the solubility of extrinsic dopants. The computational prediction of dopability has a multi-decade history in microelectronic and optoelectronic materials (e.g. III-V compounds, 1 transparent conducting oxides 2,3 ). Successful computational prediction of dopability has been enabled by the accurate description of native defect chemistry, their formation energies and the absolute position of band edges in these materials.

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“…The mobility of Sb 2 Se 3 along the [0 0 1] direction can be as high as 20 cm 2 V −1 s −1 , and the electron diffusion length along the [0 0 1] direction under high illumination is 1.7 µm . First‐principles theoretical calculations demonstrated that the electrical properties of antimony chalcogenides were ruled by native point defects (mainly antisites) and that these materials could lead to high‐efficiency solar cells because of their ultimate structural and electronic/optical properties . Typical properties of antimony chalcogenides are summarized in Table .…”

Section: Basic Properties Of Antimony Chalcogenide Materialsmentioning

confidence: 99%

Review of Recent Progress in Antimony Chalcogenide‐Based Solar Cells: Materials and Devices

et al. 2019

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Antimony chalcogenides such as Sb2S3, Sb2Se3, and Sb2(SxSe1−x)3 have emerged as very promising alternative solar absorber materials due to their high stability, abundant elemental storage, nontoxicity, low‐cost, suitable tunable bandgap, and high absorption coefficient. Remarkable achievements have been made in antimony chalcogenide solar cells in the past few decades, with the power conversion efficiency (PCE) currently reaching 9.2%, which is close to the PCE level required for industrial applications. To facilitate the realization of highly efficient antimony chalcogenide solar cells in the future, a comprehensive review of antimony chalcogenide‐based materials and photovoltaic devices is presented. First, the fundamental physical properties and preparation methods of antimony chalcogenide‐based materials are outlined, and then, notable recent developments in antimony chalcogenide‐based photovoltaic devices with various architectures are highlighted. Finally, the most prominent limitations are described, and approaches to achieving remarkable advances in antimony chalcogenide solar cells in the future are provided.

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Unraveling the Native Conduction of Trichalcogenides and Its Ideal Band Alignment for New Photovoltaic Interfaces

Cited by 64 publications

References 66 publications

Vapor transport deposition of antimony selenide thin film solar cells with 7.6% efficiency

Vapor transport deposition of antimony selenide thin film solar cells with 7.6% efficiency

First-principles calculation of intrinsic defect chemistry and self-doping in PbTe

Review of Recent Progress in Antimony Chalcogenide‐Based Solar Cells: Materials and Devices

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