The Structure and Properties of Amorphous Indium Oxide

Buchholz, D. Bruce; Ma, Qing; Alducin, Diego; Ponce, Arturo; José–Yacamán, Miguel; Khanal, Rabi; Medvedeva, Julia E.; Chang, Robert P. H.

doi:10.1021/cm502689x

Cited by 197 publications

(197 citation statements)

References 44 publications

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“…Structural parameters of Bi‐0%, Bi‐0.5%, and Bi 2 O 3 reference samples were quantitatively determined through fitting of EXAFS spectra (Figure S6, Supporting Information) as summarized in Table S1 (Supporting Information). In theory, In 2 O 3 has the bixbyite crystal structure, with all indium cations surrounded by six oxygen atoms (CN In—O = 6) and two distinct sets of adjacent polyhedral In—In neighbors (CN In−In = 6, at a distance of ≈3.34 Å, and CN In—In* = 6, at a distance of ≈3.83 Å) 27. In the present study, the prepared Bi‐0% sample has longer In—In distances (3.36 and 3.84 Å) and lower coordination numbers (5.1 and 3.1), suggesting structural distortion caused by defects, which is consistent with the observed presence of surface hydroxide and oxygen vacancy 28.…”

Section: Resultsmentioning

confidence: 99%

Tailoring Surface Frustrated Lewis Pairs of In₂O₃₋_x(OH)_y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO₂ by Isomorphous Substitution of In³⁺ with Bi³⁺

et al. 2018

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Frustrated Lewis pairs (FLPs) created by sterically hindered Lewis acids and Lewis bases have shown their capacity for capturing and reacting with a variety of small molecules, including H2 and CO2, and thereby creating a new strategy for CO2 reduction. Here, the photocatalytic CO2 reduction behavior of defect‐laden indium oxide (In2O3− x(OH)y) is greatly enhanced through isomorphous substitution of In3+ with Bi3+, providing fundamental insights into the catalytically active surface FLPs (i.e., In—OH···In) and the experimentally observed “volcano” relationship between the CO production rate and Bi3+ substitution level. According to density functional theory calculations at the optimal Bi3+ substitution level, the 6s2 electron pair of Bi3+ hybridizes with the oxygen in the neighboring In—OH Lewis base site, leading to mildly increased Lewis basicity without influencing the Lewis acidity of the nearby In Lewis acid site. Meanwhile, Bi3+ can act as an extra acid site, serving to maximize the heterolytic splitting of reactant H2, and results in a more hydridic hydride for more efficient CO2 reduction. This study demonstrates that isomorphous substitution can effectively optimize the reactivity of surface catalytic active sites in addition to influencing optoelectronic properties, affording a better understanding of the photocatalytic CO2 reduction mechanism.

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Section: Resultsmentioning

confidence: 99%

Tailoring Surface Frustrated Lewis Pairs of In₂O₃₋_x(OH)_y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO₂ by Isomorphous Substitution of In³⁺ with Bi³⁺

et al. 2018

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“…Hence, instead of classical atomistic approaches commonly employed for modeling of glasses, quantum-mechanical molecular dynamics simulations combined with accurate densityfunctional calculations are required for AOSs in order to reliably describe the formation of both shallow and deep defects responsible for carrier generation and the charge transport limited by electron scattering and trapping. In addition, accurate characterization of the structural features beyond the first shell (i.e., beyond the nearest neighbors) is necessary in order to explain the high sensitivity of the AOSs properties to the deposition [84] and post-deposition conditions, [64] particularly oxygen environment, [85] as well as the chemical composition of the sample. [67,86] In this work, ab initio MD simulations and hybrid-functional DFT-based electronic structure calculations are performed i) to systematically study the local and medium-range structural characteristics of several prototype In-based oxides with different degree of amorphization, oxygen stoichiometry, cation composition, and/or lattice strain and ii) to connect the structural peculiarities to the resulting electronic, optical, or thermal properties of each material.…”

Section: Mechanical Brittle Bendablementioning

confidence: 99%

“…Consequently, the two peaks in the In-In distribution are nearly indistinguishable and hard to resolve experimentally (i.e., the coordination number and Debye-Waller factor for the second and third shells cannot be uniquely fit). Yet, information regarding the In-In shells is essential for understanding the properties of AOSs: it has been shown that medium-range ordering plays a crucial role in the carrier transport of amorphous indium oxide [84] as discussed in the next section.…”

Section: Key Structural Properties Of Amorphous Indium Oxidementioning

confidence: 99%

“…[84] Accordingly, the transport regimes across the transition may be classified as band conductivity limited by grain boundaries (Hall mobility μ = 70 cm 2 V −1 s −1 for T d > 400 °C); multiphase scattering/percolation (μ = 20-40 cm 2 V −1 s −1 for T d = 50-300 °C); and electron localization in the amorphous phase (μ = 20 cm 2 V −1 s −1 for T d < -50 °C). Strikingly, however, when the crystalline fraction of In 2 O 3 drops to zero at T d = 0 °C, the Hall carrier mobility reaches as much as 60 cm 2 V −1 s −1 , nearly the value measured in undoped crystalline In 2 O 3 .…”

Section: Properties Of Indium Oxide Across Crystalline To Amorphous Tmentioning

confidence: 99%

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Recent Advances in Understanding the Structure and Properties of Amorphous Oxide Semiconductors

Medvedeva

Buchholz

Chang

2017

Adv Elect Materials

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conductivity. [1] Following the discovery of SnO 2 with a similar unique combination of properties, [2] several patents were filed in the 1940s to employ TCOs as antistatic coatings and transparent heaters-long before the discovery of the now well-known Sn-doped In 2 O 3 (ITO) and Al-doped ZnO, [3] widely employed as flat panel display electrodes in the past decades. Despite great technological demand for TCOs [4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] and extensive experimental efforts to improve the conductivity via impurity doping, [21,22] to tune the work function and carrier concentration via cation composition, [23][24][25][26][27][28] to achieve two-dimensional transport via heterointerfaces, [29] and to p-dope the oxides toward active layers of transparent electronics, [30][31][32] theoretical understanding of these fascinating materials has lagged behind significantly. The first electronic band structure of ITO was calculated in 2001; [33] the role of native defects in prototype TCOs was understood after 2002; [34][35][36][37] the properties of multi-cation TCOs were first considered in 2004 [37][38][39][40][41][42] followed by modeling of novel TCO hosts [43,44] and spin-dependent transport in transition-metal-doped TCOs; [45] the nature of the band gap in In 2 O 3 was clarified in 2008; [46] and a first highthroughput search for p-type TCOs was performed in 2013. [47] Complex oxides that consist of multiple post-transition metals, such as InGaZnO 4 , have recently become competitive with silicon as the active transistor layer to drive arrays of pixels in large area displays. [9,[13][14][15][16][17][18][19]24] As the billion-dollar display industry moves forward, the amorphous phase of the complex oxides is favored both for flexible and high-resolution display applications. [13][14][15][16][48][49][50][51][52][53][54][55][56][57][58][59] The unique properties of AOSs were first demonstrated in 1990, [60] and the research area has been growing exponentially since then. Unlike Si-based semiconductors, AOSs were shown to exhibit optical, electrical, thermal, and mechanical properties that are comparable or even superior to those possessed by their crystalline counterparts. [48][49][50][51][52][53][54][55][56][57][58] Table 1 summarizes the key physical properties of best-performing crystalline TCOs and AOSs; the differences (or the lack thereof) between the two will be discussed in detail in the respective sections below.

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“…Some important findings related to the internal structure of metallic glass, e.g., short-range order [2,3], medium-range order [4,5], polymorphism [6], and long-range topological order [7], have been reported recently. Effort has also been devoted to the study of local atomic environment [8,9] and lithium transport [10] in other kinds of amorphous materials. Furthermore, their specific atomic arrangement enables amorphous materials to exhibit high performance in mechanics and catalysis [11][12][13][14], as well as interesting magnetic properties [15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Tailoring the shape of amorphous nanomaterials: recent developments and applications

2015

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Nanoscale amorphous materials are very important member of the non-crystalline solids family and have emerged as a new category of advanced materials. However, morphological control of amorphous nanomaterials is very difficult because of the atomic isotropy of their internal structures. In this review, we introduce some emerging innovative methods to fabricate well-defined, regular-shaped amorphous nanomaterials. We then highlight some examples to evaluate the use of these amorphous materials in electrodes, and their optical response. There is still plenty of room to explore the amorphous world. As researchers continue to advance the scientific tools that underpin the concepts related to "amorphous", additional applications of these materials will emerge. Their controlled synthesis will undoubtedly attain new heights in the discipline of nanomaterials, and allow nanoscale amorphous materials to become more sophisticated, diverse, and mainstream.

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The Structure and Properties of Amorphous Indium Oxide

Cited by 197 publications

References 44 publications

Tailoring Surface Frustrated Lewis Pairs of In₂O₃₋_x(OH)_y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO₂ by Isomorphous Substitution of In³⁺ with Bi³⁺

Tailoring Surface Frustrated Lewis Pairs of In₂O₃₋_x(OH)_y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO₂ by Isomorphous Substitution of In³⁺ with Bi³⁺

Recent Advances in Understanding the Structure and Properties of Amorphous Oxide Semiconductors

Tailoring the shape of amorphous nanomaterials: recent developments and applications

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The Structure and Properties of Amorphous Indium Oxide

Cited by 197 publications

References 44 publications

Tailoring Surface Frustrated Lewis Pairs of In2O3−x(OH)y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO2 by Isomorphous Substitution of In3+ with Bi3+

Tailoring Surface Frustrated Lewis Pairs of In2O3−x(OH)y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO2 by Isomorphous Substitution of In3+ with Bi3+

Recent Advances in Understanding the Structure and Properties of Amorphous Oxide Semiconductors

Tailoring the shape of amorphous nanomaterials: recent developments and applications

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Tailoring Surface Frustrated Lewis Pairs of In₂O₃₋_x(OH)_y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO₂ by Isomorphous Substitution of In³⁺ with Bi³⁺

Tailoring Surface Frustrated Lewis Pairs of In₂O₃₋_x(OH)_y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO₂ by Isomorphous Substitution of In³⁺ with Bi³⁺