Combinatorial Tuning of Structural and Optoelectronic Properties in Cu Zn1−S

Woods‐Robinson, Rachel; Han, Yanbing; Mangum, John S.; Melamed, Celeste L.; Gorman, Brian P.; Mehta, Apurva; Persson, Kristin A.; Zakutayev, Andriy

doi:10.1016/j.matt.2019.06.019

Cited by 29 publications

(38 citation statements)

References 85 publications

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“…Cu-alloyed zinc sulfide (Cu x Zn 1−x S), the final nonoxide material covered in this review, represents a special case, as it can be synthesized either as a heterostructural alloy 101 or as a nanocomposite of Cu 2 S and ZnS, in which high conductivity stems from the Cu 2 S phase and transparency is imparted by the wide bandgap of ZnS. 102 In the case of the alloy, p-type conductivity up to 40 S cm −1 and a bandgap of 3.1 eV have been reported.…”

Section: Copper Zinc Sulfidementioning

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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Section: Copper Zinc Sulfidementioning

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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“…This is different from an exhaustive search data-directed approach in which the discovery of materials with a given functionality is based on high-throughput computation of all (or many) possible combinations of atomic identities, composition, and structures. 32,33 This is also different from traditional machine learning, in that inverse design relies on the use of an explicitly causal physical mechanism rather than on the correlation of, say, atomistic features with the target functionality. [34][35][36] The main accomplishments of the current work are: (1) the development of the definition of the Rashba scale: all materials with larger than certain value a R have band anti-crossing, and below that threshold none has band anti-crossing; (2) the demonstration of how anticrossing bands can be identified form the atomic orbital contribution to the band structure; (3) the establishment of TRIs; (4) the inverse design of 34 strong Rashba compounds and 165 weak Rashba compounds based on the proposed theory, i.e., the anti-crossing as design principle for strong Rashba materials.…”

Section: Progress and Potentialmentioning

confidence: 99%

The Rashba Scale: Emergence of Band Anti-crossing as a Design Principle for Materials with Large Rashba Coefficient

Acosta

Ogoshi

Fazzio

et al. 2020

Matter

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The generation of spin currents from charge currents forms the basis for a new form (spintronics) of electronics. This, however, requires finding materials capable of having large splitting between their spin bands. Thus far, no hallmark has been known to aid the hunt for such compounds. Using the inverse design approach, we find an unsuspected quantum hallmark-the existence of anti-crossing between energy bands-to be the give-away signal. This enabled identification of 34 compounds with unusually strong spin splitting.

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“…We note that in our alloy system Zn x Zr 1-x N y , the presence of a lower density hexagonal phase (BN, here) located between two higher density cubic phases (RS and BX, here) is indicative of a phenomenon in heterovalent heterostructural alloys called "negative pressure" alloys. [42,43] Additionally, these calculations use the nominal valence of the cations, namely, Zn 2+ and Zr 4+ ; we do not perform defect calculations nor vary cation oxidation states. Rigorous examination of alloy phase space would require an in-depth calculation of a temperature phase diagram, which is beyond our scope, but this approximation supports our experimental observation of a phase change from RS to BN as x increases in Zn x Zr 1-x N y .…”

Section: Configurational Enthalpy Of Random Disordermentioning

confidence: 99%

The role of disorder in the synthesis of metastable zinc zirconium nitrides

Woods‐Robinson¹,

Stevanović²,

Lany³

et al. 2020

Preprint

Self Cite

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In materials science, it is often assumed that the most thermodynamically stable crystal structure is the easiest polymorph to synthesize. Ternary nitride materials, with many possible metastable polymorphs, provide a domain to test this assumption; for example, ZnZrN 2 is predicted to have an unusual layered "wurtsalt" crystal structure and exciting optoelectronic properties, but can it be realized experimentally? Here, we synthesize hundreds of Zn x Zr 1-x N y thin film samples, and find metastable rocksalt-derived or boron-nitride-derived structures rather than the thermodynamically stable wurtsalt structure. Computations show that this divergence is due to both entropic and enthalpic stabilization effects. Rocksalt-and boron-nitride-derived structures become the most stable polymorphs in the presence of disorder because of higher tolerances to cation cross-substitution and off-stoichiometry than the wurtsalt structure. By understanding the role of disorder tolerance in the synthesis of metastable polymorphs, we can enable more accurate predictions of synthesizable crystal structures and their achievable material properties.

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Combinatorial Tuning of Structural and Optoelectronic Properties in Cu Zn1−S

Cited by 29 publications

References 85 publications

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

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

The Rashba Scale: Emergence of Band Anti-crossing as a Design Principle for Materials with Large Rashba Coefficient

The role of disorder in the synthesis of metastable zinc zirconium nitrides

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