Bond angle distribution in amorphous germania and silica

Neuefeind, J.; Liss, Klaus-Dieter

doi:10.1002/bbpc.19961000812

Cited by 164 publications

(125 citation statements)

References 42 publications

(72 reference statements)

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“…[17], but in agreement a more recent calculation that used a larger range of X-ray energies, and hence k as well [18]. Not including d-state symmetries with Gaussian radial components yield the ionic bonding solution with bond angle of 180…”

Section: Bonding Constraints For Sro and Mrosupporting

confidence: 78%

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Symmetry determined medium range order (MRO) contributions to the first sharp diffraction peak (FSDP) in non‐crystalline oxide and chalcogenide glasses

Lucovsky

Phillips

2009

Physica Status Solidi (b)

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The first sharp diffraction peak (FSDP) in the structure factor, S(Q), obtained from X‐ray and neutron diffraction data, is a characteristic feature of oxide and chalcogenide glasses. This feature reflects intermediate, or medium range order (MRO), and is expressed in terms of two experimentally determined parameters, the position, Q1(Å−1), and the full‐width at half‐maximum (FWHM), ΔQ1(Å−1), of the FSDP peak. These parameters determine a correlation length R = 2π/Q1(Å−1) and a coherence length L = 2π/ΔQ1(Å−1) that result from symmetry‐determined contributions to the fundamental electronic structures of SiO2 and GeSe2. Narrow distributions of third neighbor SiO and GeSe pair correlation distances are forced by strongly correlated symmetries of Si and Ge d‐states connected through intervening O and Se atoms, as well as Se inter‐atom lone‐pair repulsions in GeSe2. The local bonding of threefold coordinated B‐atoms in B2O3 is planar rather than tetragonal and a similar O 2pπB 3dπ overlap is symmetry forbidden. Instead symmetry allowed O 2pπB 3pπ bonding interactions play the determining role in promoting second‐neighbor BO atom coupling through intervening O‐atoms, thereby extending the correlation length scale into the MRO regime.

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Section: Bonding Constraints For Sro and Mrosupporting

confidence: 78%

“…[20,21]. The staggered configuration in these studies is the geometric arrangement that is required by the symmetry constrains of the O 2pπ-Si 3dπ overlap that provides the charge transfer that stabilizes the Si-O-Si bond angle at a value consistent with the latest X-ray diffraction studies [18].…”

Section: Bonding Constraints For Sro and Mromentioning

confidence: 88%

Symmetry determined medium range order (MRO) contributions to the first sharp diffraction peak (FSDP) in non‐crystalline oxide and chalcogenide glasses

Lucovsky

Phillips

2009

Physica Status Solidi (b)

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“…The 9-atom clusters are terminated either by i) Si* pseudo-atoms that preserve Si and O core levels, and dipole moments, or ii) Hatoms with essentially equivalent results. The ab initio calculations give an average Si-O-Si bond angle of 149±1°, and a bond angle distribution of ~19°±2° in good agreement with recently published results [9,10]. This distribution is markedly different from the >30° bond angle spread of Mozzi and Warren [11].…”

Section: Ab Initio Calculationssupporting

confidence: 86%

Ab initio calculations for photo‐darkening and photo‐induced structural changes in As ₂ S ₃ and GeS ₂

Lucovsky

Paesler

2004

phys. stat. sol. (c)

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Using ab initio calculations of the electronic structure, this article identifies the optical absorption transitions that initiate photo-darkening. This approach includes an intrinsic network relaxation mechanism for the initiation of photo-induced structural changes in As 2 S 3 that does not require intra-molecular bond scission-induced defect formation, and is limited to alloy compositions such as As 2 S 3 and GeS 4 in which selforganization at the glass transition temperature minimizes bond strain in the annealed or relaxed state. For alloy compositions outside of a narrow compositional window in which this type of self-organization occurs, defect formation via intra-molecular bond scission contributes to the reported photo-induced structural changes, as in GeSe 2 and elemental Se. In the context of constraint theory, As 2 S 3 an ideal optimallyconstrained glass in which the number of bonding constraints per atom exactly equals the network dimensionality, whilst GeSe 2 is over-constrained, and Si is floppy, or under-constrained.

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“…A recent neutron and X-ray diffraction investigation [35] has shown that the o using high-energy X-ray diffraction [45]. This bond angle and its distribution are lower than in the case of vitreous silica.…”

Section: Neutron and X-ray Diffractionmentioning

confidence: 99%

The structure of amorphous, crystalline and liquid GeO₂

Micoulaut

Cormier

Henderson

2006

J. Phys.: Condens. Matter

228

252

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Abstract. Germanium dioxide (GeO 2 ) is a chemical analogue of SiO 2 . Furthermore, it is also to some extent a structural analogue, as the low and high-pressure short-range order (tetrahedral and octahedral) is the same. However, a number of differences exist. For example, the GeO 2 phase diagram exhibits a smaller number of polymorphs, and all three GeO 2 phases (crystalline, glass, liquid) have an increased sensitivity to pressure, undergoing pressure induced changes at much lower pressures than their equivalent SiO 2 analogues. In addition, differences exist in GeO 2 glass in the medium range order, resulting in the glass transition temperature of germania being much lower than for silica. This review highlights the structure of amorphous GeO 2 by different experimental (e.g., Raman and NMR spectroscopy, neutron and x-ray diffraction) and theoretical methods (e.g., classical molecular dynamics, ab initio calculations). It also addresses the structure of liquid and crystalline GeO 2 that have received much less attention. Furthermore, we compare and contrast the structural differences between GeO 2 and SiO 2 , as well as, along the GeO 2 − SiO 2 join. It is probably a very timely review as interest in this compound, that can be investigated in the liquid state at relatively low temperatures and pressures, continues to increase.

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Bond angle distribution in amorphous germania and silica

Cited by 164 publications

References 42 publications

Symmetry determined medium range order (MRO) contributions to the first sharp diffraction peak (FSDP) in non‐crystalline oxide and chalcogenide glasses

Symmetry determined medium range order (MRO) contributions to the first sharp diffraction peak (FSDP) in non‐crystalline oxide and chalcogenide glasses

Ab initio calculations for photo‐darkening and photo‐induced structural changes in As ₂ S ₃ and GeS ₂

The structure of amorphous, crystalline and liquid GeO₂

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Bond angle distribution in amorphous germania and silica

Cited by 164 publications

References 42 publications

Symmetry determined medium range order (MRO) contributions to the first sharp diffraction peak (FSDP) in non‐crystalline oxide and chalcogenide glasses

Symmetry determined medium range order (MRO) contributions to the first sharp diffraction peak (FSDP) in non‐crystalline oxide and chalcogenide glasses

Ab initio calculations for photo‐darkening and photo‐induced structural changes in As 2 S 3 and GeS 2

The structure of amorphous, crystalline and liquid GeO2

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Ab initio calculations for photo‐darkening and photo‐induced structural changes in As ₂ S ₃ and GeS ₂

The structure of amorphous, crystalline and liquid GeO₂