Electronic structure and defect properties of 
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 from hybrid functional and many-body perturbation theory calculations: A possible ambipolar transparent conductor

Varley, Joel B.; Lordi, Vincenzo; Miglio, Anna; Hautier, Geoffroy

doi:10.1103/physrevb.90.045205

Cited by 33 publications

(31 citation statements)

References 52 publications

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“…The HOMO‐LUMO band gap energy for the B 6 O crystal is 2.47 eV in good agreement with the earlier first principles GGA simulation results of 1.9‐2.4 eV . This value however is <2.93‐3.0 eV estimated using the G 0 W 0 approximation . For the amorphous state, the HOMO‐LUMO band gap energy is fairly small and about 0.51 eV.…”

Section: Resultssupporting

confidence: 88%

Amorphous boron suboxide

Durandurdu

2019

J Am Ceram Soc

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We study the atomic structure and the electronic and mechanical properties of amorphous boron suboxide (B 6 O) using an ab initio molecular dynamic technique. The amorphous network is attained from the rapid solidification of the melt and found to consist of boron and oxygen-rich regions. In the boron-rich regions, boron atoms form mostly perfect or imperfect pentagonal pyramid-like configurations that normally yield the construction of ideal and incomplete B 12 molecules in the model. In addition to the B 12 molecules, we also observe the development of a pentagonal bipyramid (B 7 ) molecule in the noncrystalline structure. In the oxygen-rich regions, on the other hand, boron and oxygen atoms form threefold and twofold coordinated motifs, respectively. The boron-rich and oxygen-rich regions indeed represent structurally the characteristic of amorphous boron and boron trioxide (B 2 O 3 ). The amorphous phase possesses a small band gap energy with respect to the crystal. On the bases of the localization of the tail states, we suggest that the p-type doping might be more convenient than the n-type doping in amorphous B 6 O. Bulk modulus and Vickers hardness of the noncrystalline configuration is estimated are be 106 and 13-18 GPa, respectively, which are noticeably less than those of the crystalline structure. Such a noticeable decrease in the mechanical properties is attributed to the presence of open structured B 2 O 3 glassy domains in the amorphous model. K E Y W O R D Samorphous, boron suboxide, hardness

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Section: Resultssupporting

confidence: 88%

Amorphous boron suboxide

Durandurdu

2019

J Am Ceram Soc

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“…The energy‐dispersive X‐ray spectroscopy (EDS) measurement on a single rhombohedra particle of R‐B 6 O shows that only B and O elements can be detected (Cu is from the Cu foil substrate), indicating the high purity of the synthetic R‐B 6 O (Table S2, Supporting Information). The approximate atomic ratio of B to O in R‐B 6 O is about 7.24:1, which is in accordance with the previous studies, indicating that there are large amount of defects in B 6 O and the real formula should be “B 6 O 1− x .” To further investigate the surface condition, electron paramagnetic resonance (EPR) spectra were performed on the B 6 O samples. As shown in Figure S10, Supporting Information, a strong EPR signal is detected, which is a characteristic of single electron‐trapped (or paramagnetic) oxygen vacancies in B 6 O.…”

Section: Methodssupporting

confidence: 87%

Green Synthesis of Lamellae Rhombohedra Boron Suboxide for Efficient Photoreduction Catalysis with Visible Light Response

et al. 2019

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Exploring novel photocatalysts is one of the primary missions for photocatalytic solar energy conversion. Metal‐free photocatalysts are of particular recent interest due to the drawbacks of conventional metal‐based photocatalysts, such as high cost, lack of abundance, and environmental hazardousness. A facile, environmental‐benign, and scalable synthetic strategy of well‐crystalline B6O particles is presented. The ultralow synthetic temperature of 90 °C and ambient pressure are the most mild synthetic conditions for this material. The prepared B6O shows a lamellae structure and regular rhombohedra morphology with a remarkably large surface area of 93.82 m2 g−1. It is proposed that the mild crystallization via a twin plane re‐entrant edge mechanism may contribute to the unique morphology. The rhombohedra B6O “R‐B6O” is explored to perform efficient photocatalytic water splitting and CO2 reduction without loading noble metal cocatalysts. The R‐B6O can also be used as a stable photocathode material for photoelectrochemical water reduction under visible light irradiation. The current work presents a new member to the family of metal‐free photocatalysts and photocathode materials.

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“…The properties of importance for a TCO are wellknown (transparency, mobility, high dopability) and can be related to the fundamental electronic structure of the oxide [4,16,17]. This has led to an important body of computationally or chemically driven searches for good TCOs candidates [12][13][14][18][19][20][21][22][23][24].…”

mentioning

confidence: 99%

Influence of the “second gap” on the transparency of transparent conducting oxides: An ab initio study

Waroquiers

Rignanese

et al. 2016

Applied Physics Letters

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Transparent conducting oxides (TCOs) are essential to many technologies. These materials are doped (n-or p-type) oxides with a large enough band gap (ideally >3 eV) to ensure transparency. However, the high carrier concentration present in TCOs lead additionally to the possibility for optical transitions from the occupied conduction bands to higher states for n-type materials and from lower states to the unoccupied valence bands for p-type TCOs. The "second gap" formed by these transitions might limit transparency and a large second gap has been sometimes proposed as a design criteria for high performance TCOs. Here, we study the influence of this second gap on optical absorption using ab initio computations for several well-known n-and p-type TCOs. Our work demonstrates that most known n-type TCOs do not suffer from second gap absorption in the visible even at very high carrier concentrations. On the contrary, p-type oxides show lowering of their optical transmission for high carrier concentrations due to second gap effects. We link this dissimilarity to the different chemistries involved in n-versus typical p-type TCOs. Quantitatively, we show that second gap effects lead to only moderate loss of transmission (even in p-type TCOs) and suggest that a wide second gap, while beneficial, should not be considered as a needed criteria for a working TCO.

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Electronic structure and defect properties of B6O from hybrid functional and many-body perturbation theory calculations: A possible ambipolar transparent conductor

Cited by 33 publications

References 52 publications

Amorphous boron suboxide

Amorphous boron suboxide

Green Synthesis of Lamellae Rhombohedra Boron Suboxide for Efficient Photoreduction Catalysis with Visible Light Response

Influence of the “second gap” on the transparency of transparent conducting oxides: An ab initio study

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