Pressure-Induced Phase Transition and Band Gap Decrease in Semiconducting β-Cu2V2O7

Turnbull, Robin; González‐Platas, Javier; Rodrı́guez, F.; Liang, Akun; Popescu, Cătălin; He, Zhangzhen; Santamarı́a-Pérez, D.; Rodríguez-Hernández, Placida; Múñoz, A.; Errandonea, Daniel

doi:10.1021/acs.inorgchem.1c03878

Cited by 15 publications

(8 citation statements)

References 65 publications

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“…The range of band-gap error values is 0.00–0.05 eV (Table S3, Supporting Information). Our results showing a large change of the band gap with pressure are consistent with a highly compressible material . The method used to determine the band-gap energy using Tauc plots tends to give an underestimated value .…”

Section: Resultssupporting

confidence: 82%

“…Our results showing a large change of the band gap with pressure are consistent with a highly compressible material. 38 The method used to determine the band-gap energy using Tauc plots tends to give an underestimated value. 39 However, due to a lack of observation of any excitonic peak and even restricted plateau area at low pressures in the absorption spectra (due to instrument limitation), we could not use the Elliott−Toyozawa model for accurate band-gap determination.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Pressure-Induced Phase Transitions and Amorphization in HgCN(NO₃)

Jain,

Garg,

Chitnis

et al. 2023

J. Phys. Chem. C

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In situ high-pressure Raman spectroscopic, X-ray diffraction (XRD), and optical absorption studies on negative thermal expansion material, HgCN(NO3), were carried out under a nonhydrostatic pressure environment. High-pressure X-ray diffraction study illustrates a structural phase transition from hexagonal (P6/mmm) to monoclinic-I (P21/n) at 0.4 GPa and monoclinic-I (P21/n) to a second high-pressure phase above 2.6 GPa. Vibrational modes corresponding to the Hg–C–N bending mode and N–OII stretching in bidentate nitrate mode show softening up to ∼8.1 GPa. Broadening of the diffraction peaks beyond ∼8 GPa indicates the onset of a disordered phase, which eventually transforms into an amorphous phase beyond ∼15.8 GPa. The first structural transition at 0.4 GPa is accompanied by an indirect-to-indirect band-gap transition, resulting in an increase in the optical band gap. However, at the onset of the disorder, there is an indirect-to-direct band-gap transition, leading to an abrupt decrease (∼20.5%) in the band gap.

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Section: Resultssupporting

confidence: 82%

Section: ■ Results and Discussionmentioning

confidence: 99%

Pressure-Induced Phase Transitions and Amorphization in HgCN(NO₃)

Jain,

Garg,

Chitnis

et al. 2023

J. Phys. Chem. C

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“…The second fact that facilitates the reduction of volume in CuMoO 4 is that it can be achieved by tilting of the polyhedra. It should be noted that with respect to its polyhedral constitution, CuMoO 4 is more similar to Cu 3 V 2 O 8 and Cu 2 V 2 O 7 [45,46] than to typical orthomolybdates [47,48]. This is consistent in that the two vanadates have bulk moduli of 52 and 64 GPa, respectively; values that are comparable to the bulk modulus of αand γ-CuMoO 4 .…”

Section: Eigenvaluessupporting

confidence: 60%

An Investigation of the Pressure-Induced Structural Phase Transition of Nanocrystalline α-CuMoO4

2022

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The structural behavior of nanocrystalline α-CuMoO4 was studied at ambient temperature up to 2 GPa using in situ synchrotron X-ray powder diffraction. We found that nanocrystalline α-CuMoO4 undergoes a structural phase transition into γ-CuMoO4 at 0.5 GPa. The structural sequence is analogous to the behavior of its bulk counterpart, but the transition pressure is doubled. A coexistence of both phases was observed till 1.2 GPa. The phase transition gives rise to a change in the copper coordination from square-pyramidal to octahedral coordination. The transition involves a volume reduction of 13% indicating a first-order nature of the phase transition. This transformation was observed to be irreversible in nature. The pressure dependence of the unit-cell parameters was obtained and is discussed, and the compressibility analyzed.

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“…Due to this enormous pressure range, even planetary interiors can be modeled with a DAC. However, it should be noted that a pressure of less than 1 GPa can also induce effects like phase transitions and band gap alterations 20 …”

Section: Introductionmentioning

confidence: 99%

Computational high‐pressure chemistry: Ab initio simulations of atoms, molecules, and extended materials in the gigapascal regime

Zeller,

Hsieh,

Dononelli

et al. 2024

WIREs Comput Mol Sci

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The field of liquid‐phase and solid‐state high‐pressure chemistry has exploded since the advent of the diamond anvil cell, an experimental technique that allows the application of pressures up to several hundred gigapascals. To complement high‐pressure experiments, a large number of computational tools have been developed. These techniques enable the simulation of chemical systems, their sizes ranging from single atoms to infinitely large crystals, under high pressure, and the calculation of the resulting structural, electronic, and spectroscopic changes. At the most fundamental level, computational methods using carefully tailored wall potentials allow the analytical calculation of energies and electronic properties of compressed atoms. Molecules and molecular clusters can be compressed either via mechanochemical approaches or via more sophisticated computational protocols using implicit or explicit solvation approaches, typically in combination with density functional theory, thus allowing the simulation of pressure‐induced chemical reactions. Crystals and other periodic systems can be routinely simulated under pressure as well, both statically and dynamically, to predict the changes of crystallographic data under pressure and high‐pressure crystal structure transitions. In this review, the theoretical foundations of the available computational tools for simulating high‐pressure chemistry are introduced and example applications demonstrating the strengths and weaknesses of each approach are discussed.This article is categorized under: Structure and Mechanism > Computational Materials Science Electronic Structure Theory > Ab Initio Electronic Structure Methods Software > Simulation Methods

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Pressure-Induced Phase Transition and Band Gap Decrease in Semiconducting β-Cu₂V₂O₇

Cited by 15 publications

References 65 publications

Pressure-Induced Phase Transitions and Amorphization in HgCN(NO₃)

Pressure-Induced Phase Transitions and Amorphization in HgCN(NO₃)

An Investigation of the Pressure-Induced Structural Phase Transition of Nanocrystalline α-CuMoO4

Computational high‐pressure chemistry: Ab initio simulations of atoms, molecules, and extended materials in the gigapascal regime

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Pressure-Induced Phase Transition and Band Gap Decrease in Semiconducting β-Cu2V2O7

Cited by 15 publications

References 65 publications

Pressure-Induced Phase Transitions and Amorphization in HgCN(NO3)

Pressure-Induced Phase Transitions and Amorphization in HgCN(NO3)

An Investigation of the Pressure-Induced Structural Phase Transition of Nanocrystalline α-CuMoO4

Computational high‐pressure chemistry: Ab initio simulations of atoms, molecules, and extended materials in the gigapascal regime

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Pressure-Induced Phase Transition and Band Gap Decrease in Semiconducting β-Cu₂V₂O₇

Pressure-Induced Phase Transitions and Amorphization in HgCN(NO₃)

Pressure-Induced Phase Transitions and Amorphization in HgCN(NO₃)