Transparent conducting materials discovery using high-throughput computing

Brunin, Guillaume; Ricci, Francesco; Ha, Viet Anh; Rignanese, Gian‐Marco; Hautier, Geoffroy

doi:10.1038/s41524-019-0200-5

Cited by 123 publications

(98 citation statements)

References 111 publications

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“…We recently carried out a study of four Sn n (S 1-x Se x ) m alloys [26], including the Pnma and rocksalt monosulphides, by performing first-principles calculations on the full sets of symmetry-inequivalent structures formed by substituting chalcogen atoms in small supercells of the parent structures [28]. In this study we also confirmed the stability of the mixed Pnma Sn(S 1-x Se x ) alloys and further predicted the effect of alloying on the structural, electrical and optical properties [26].While many large-scale modelling studies make use of (semi-)local DFT methods to evaluate and compare energetics and electrical properties [29][30][31][32], modelling lattice dynamics and in particular thermal transport can be much more resource intensive, and there are thus comparatively fewer examples of screening studies focussing on these properties [33]. As a result, despite the widespread use of alloying to tune the performance of thermoelectric materials, there has been little theoretical investigation into how composition affects the dynamics and related properties.…”

supporting

confidence: 72%

“…While many large-scale modelling studies make use of (semi-)local DFT methods to evaluate and compare energetics and electrical properties [29][30][31][32], modelling lattice dynamics and in particular thermal transport can be much more resource intensive, and there are thus comparatively fewer examples of screening studies focussing on these properties [33]. As a result, despite the widespread use of alloying to tune the performance of thermoelectric materials, there has been little theoretical investigation into how composition affects the dynamics and related properties.…”

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confidence: 99%

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Lattice dynamics of Pnma Sn(S_1–xSe_x) solid solutions: energetics, phonon spectra and thermal transport

Skelton

2020

J. Phys. Energy

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Alloying is widely used as a means to fine-tune the properties of thermoelectric materials by reducing the lattice thermal conductivity. However, the effects of compositional variation on the lattice dynamics of alloy systems are not well understood, due in part to the difficulty of building realistic first-principles models of structurally-complex solid solutions. This work builds on our previous study of Sn n (S 1-x Se x ) m solid solutions (Gunn et al 2019 Chem. Mater. 31 3672) to explore the lattice dynamics of the Pnma Sn(S 1-x Se x ) system, which has been widely studied for potential thermoelectric applications. We find that the vibrational internal energy and entropy have a large quantitative impact on the mixing free energy and are likely to be particularly important in alloy systems with competing phases. The thermodynamically-averaged phonon dispersions and density of states curves show that alloying preserves the structure of the low-frequency bands of modes associated with the Sn sublattice but broadens the high-frequency chalcogen bands into a near-continuous spectrum at the 50/50 mixed composition. This results in a general reduction in the phonon mode group velocities and an increase in the number of energy-conserving scattering channels for heat-carrying low-frequency modes, which is consistent with the decrease in thermal conductivity observed in experimental measurements. Finally, we discuss some of the limitations of our first-principles modelling approach and propose methods to address these in future studies.OPEN ACCESS RECEIVED improving TE performance. In some cases the electronic and thermal transport can be almost completely decoupled [1], as in the 'phonon glass, electron crystal' concept [3]. All four parameters in equation (1) are implicit functions of temperature, requiring that materials are either optimised to produce a high peak ZT at a target operating temperature range or tuned to display a high ZT across a wide range of temperatures.Current flagship TE materials include PbTe, SnSe and Bi 2 Te 3 , all three of which display favourable electrical properties and intrinsically low thermal conductivity due to a combination of heavy elements and strongly anharmonic lattice dynamics [4][5][6]. However, PbTe and Bi 2 Te 3 are not suitable for widespread adoption due to the low abundance of Te, and there are also concerns with SnSe due to the environmental toxicity of Se. There has therefore been significant effort devoted to alternative systems including the more earth-abundant SnS [2] and metal oxides [7][8][9][10].Alloying is commonly used as a means to enhance thermoelectric performance, as a suitable choice of components can maintain or improve a favourable electronic structure while reducing k latt by introducing variation in atomic masses and chemical bond strength to promote stronger phonon scattering [11]. Pb(S, Se, Te), Sn(S, Se) and (Bi, Sb) 2 (Se, Te) 3 alloys have all been studied as thermoelectrics and the alloying shown to improve ZT [12][13][14][15][16][17]. Due to the r...

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confidence: 72%

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confidence: 99%

Lattice dynamics of Pnma Sn(S_1–xSe_x) solid solutions: energetics, phonon spectra and thermal transport

Skelton

2020

J. Phys. Energy

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“…13 Moreover, even with 220 S cm −1 , the performance still falls short of standard n-type TCMs that routinely display conductivity >300 S cm −1 . 3,14 With the advent of high-throughput computational screening and design approaches, numerous research articles proposing material compositions and structures with p-type conductivity and wide band gaps have been published. These predictions are based on coupling dispersion (delocalization) of the valence band (VB) with favorable defect formation chemistry in order to select materials with inherently high hole mobility and enhanced p-type dopability.…”

Section: Introductionmentioning

confidence: 99%

“…In this review, we present an overview of the experimental techniques and synthesis approaches reported on DVMs with the aim to bridge the gap between computational and experimental works on p-TCMs. The authors note that while oxide materials with promising p-type conductivity and transparency properties have received attention in the recent computational literature, 14,19 we focus herein on materials beyond oxides, as oxides are considered well-known chemistries with several synthesis approaches already at advanced stages of development.…”

Section: Introductionmentioning

confidence: 99%

Bridging the p-type transparent conductive materials gap: synthesis approaches for disperse valence band materials

Fioretti

Morales‐Masis

2020

J. Photon. Energy

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Transparent conductive materials (TCMs) with high p-type conductivity and broadband transparency have remained elusive for years. Despite decades of research, no p-type material has yet been found to match the performance of n-type TCMs. If developed, the high-performance p-type TCMs would lead to significant advances in a wide range of technologies, including thin-film transistors, transparent electronics, flat screen displays, and photovoltaics. Recent insights from high-throughput computational screening have defined design principles for identifying candidate materials with low hole effective mass, also known as disperse valence band materials. Particularly, materials with mixed-anion chemistry and nonoxide materials have received attention as being promising next-generation p-type TCMs. However, experimental demonstrations of these compounds are scarce compared to the computational output. One reason for this gap is the experimental difficulty of safely and controllably sourcing elements, such as sulfur, phosphorous, and iodine for depositing these materials in thin-film form. Another important obstacle to experimental realization is air stability or stability with respect to formation of the competing oxide phases. We summarize experimental demonstrations of disperse valence band materials, including synthesis strategies and common experimental challenges. We end by outlining recommendations for synthesizing p-type TCMs still absent from the literature and highlight remaining experimental barriers to be overcome.

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“…From that time many researchers delve into the field of TCO so that new types of TCOs with broad range applications can be prepared. Some of the widely known used TCOs include In 2 [1,[3][4][5].…”

Section: Introductionmentioning

confidence: 99%

Investigation of self-consistent site-dependent DFT + U effect on electronic band structure and optical properties of SiFe₂O₄ spinel

Idris¹,

Shaari²,

Razali³

et al. 2020

Mater. Res. Express

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The first-principle investigation of SiFe 2 O 4 (SFO) spinel was performed with the help of a plane-wave pseudopotential technique within the generalized gradient approximation (GGA) and local density approximation (LDA) as implemented in Quantum Espresso Simulation package. The Electronic band structure and optical properties of SFO spinel-type material have been investigated and discussed in this paper. The calculated band structure reveals that SFO spinel-type material is a direct bandgap semiconductor. Using GGA+U and LDA+U the band gap value so obtained is 3.52 eV and 2.96 eV respectively. The contribution to valence and conduction bands due to different bands was analyzed on the basis of the total and partial density of state. The Optical properties of SFO spinel-type material have been calculated and discussed in detail. The real, e w 1 ( ) and the imaginary, e w 2 ( ) part of the complex dielectric constants is found to be 6.52 and 5.42 at energies of 3.44 eV and 6.21 eV respectively. The refractive index n 0 ( ) and the reflectivity index w R , ( ( )) at zero energy value were found to be 1.88 and 10% respectively. We found that SFO spinel-type material has good properties for optical devices.

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Transparent conducting materials discovery using high-throughput computing

Cited by 123 publications

References 111 publications

Lattice dynamics of Pnma Sn(S_1–xSe_x) solid solutions: energetics, phonon spectra and thermal transport

Lattice dynamics of Pnma Sn(S_1–xSe_x) solid solutions: energetics, phonon spectra and thermal transport

Bridging the p-type transparent conductive materials gap: synthesis approaches for disperse valence band materials

Investigation of self-consistent site-dependent DFT + U effect on electronic band structure and optical properties of SiFe₂O₄ spinel

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Transparent conducting materials discovery using high-throughput computing

Cited by 123 publications

References 111 publications

Lattice dynamics of Pnma Sn(S1–xSex) solid solutions: energetics, phonon spectra and thermal transport

Lattice dynamics of Pnma Sn(S1–xSex) solid solutions: energetics, phonon spectra and thermal transport

Bridging the p-type transparent conductive materials gap: synthesis approaches for disperse valence band materials

Investigation of self-consistent site-dependent DFT + U effect on electronic band structure and optical properties of SiFe2O4 spinel

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Lattice dynamics of Pnma Sn(S_1–xSe_x) solid solutions: energetics, phonon spectra and thermal transport

Lattice dynamics of Pnma Sn(S_1–xSe_x) solid solutions: energetics, phonon spectra and thermal transport

Investigation of self-consistent site-dependent DFT + U effect on electronic band structure and optical properties of SiFe₂O₄ spinel