Structure and properties of densified silica glass: characterizing the order within disorder

Onodera, Yohei; Kohara, Shinji; Salmon, Philip S.; Hirata, Akihiko; Nishiyama, Norimasa; Kitani, Suguru; Zeidler, Anita; Shiga, M.; Masuno, Atsunobu; Inoue, Hiroyuki; Tahara, Shuta; Polidori, Annalisa; Fischer, Henry E.; Mori, Tatsuya; Kojima, Seiji; Kawaji, Hitoshi; Kolesnikov, A. I.; Stone, M. B.; Tucker, Matthew G.; McDonnell, Marshall T.; Hannon, Alex C.; Hiraoka, Yasuaki; Obayashi, Ippei; Nakamura, Takenobu; Akola, Jaakko; Fujii, Yasuhiro; Ohara, Koji; Taniguchi, Takashi; Sakata, Osami

doi:10.1038/s41427-020-00262-z

Cited by 66 publications

(42 citation statements)

References 50 publications

(59 reference statements)

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“…In this section, we review recent structural studies on the structure of glassy, liquid and amorphous materials by diffraction techniques combined with computer simulations aided by topological analyses [4]. Over the last 20 years, we have been working on the structure of disordered materials, oxide glasses [48,53,[56][57][58][59], amorphous oxide materials [60][61][62], chalcogenide fast phase-change materials [63][64][65][66], metallic glasses [67], water [68], high-temperature oxide melt [69][70][71], densified glass [72], and other functional materials [73,74].…”

Section: Discussionmentioning

confidence: 99%

“…It is known that the FSDP of silica glass is related to the formation of a random network, as suggested by Zachariasen [75], and the model was extended to silicate glasses, as illustrated in figure 7 of reference [86], by Mei et al It was confirmed that intermediate-range ordering (IRO) arises from the periodicity of boundaries between successive small cages in the network, formed by connected regular SiO 4 tetrahedra with shared oxygen atoms at the corners. The IRO is thus associated with the formation of a ring structure and cavities [48,72]. The second maximum, the PP, reflects the size of the local-network-forming motif, whereas the FSDP indicates the arrangement of these motifs on an intermediate range, according to Zeidler and Salmon [87].…”

Section: Glassy and Liquid Siomentioning

confidence: 99%

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Structure of disordered materials under ambient to extreme conditions revealed by synchrotron x-ray diffraction techniques at SPring-8—recent instrumentation and synergic collaboration with modelling and topological analyses

Ohara

Onodera

Murakami

et al. 2021

J. Phys.: Condens. Matter

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The structure of disordered materials is still not well understood because of insufficient experimental data. Indeed, diffraction patterns from disordered materials are very broad and can be described only in pairwise correlations because of the absence of translational symmetry. Brilliant hard x-rays from third-generation synchrotron radiation sources enable us to obtain high-quality diffraction data for disordered materials from ambient to high temperature and high pressure, which has significantly improved our grasp of the nature of order in disordered materials. Here, we introduce the progress in the instrumentation for hard x-ray beamlines at SPring-8 over the last 20 years with associated results and advanced data analysis techniques to understand the topology in disordered materials.

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Section: Discussionmentioning

confidence: 99%

Section: Glassy and Liquid Siomentioning

confidence: 99%

Structure of disordered materials under ambient to extreme conditions revealed by synchrotron x-ray diffraction techniques at SPring-8—recent instrumentation and synergic collaboration with modelling and topological analyses

Ohara

Onodera

Murakami

et al. 2021

J. Phys.: Condens. Matter

Self Cite

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“…This could indicate σ Nd depends on the state of disorder within the network structure. Both, a higher cooling rate as well as higher uniaxial stress, should increase the disorder state of the glass network [58,59]. Data using the σ Nd -parameter as a sensor for cooling rate or uniaxial stress in the elastic regime has not been previously reported.…”

Section: Us(σ Nd ) =mentioning

confidence: 99%

Coupling Raman, Brillouin and Nd3+ Photo Luminescence Spectroscopy to Distinguish the Effect of Uniaxial Stress from Cooling Rate on Soda–Lime Silicate Glass

et al. 2021

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Evolution of spectroscopic properties of a soda–lime silicate glass with different thermal history and under applied uniaxial stress was investigated using Raman and Brillouin spectroscopies as well as Nd3+ photoluminescence techniques. Samples of soda–lime silicate with a cooling rate from 6 × 10−4 to 650 K/min were prepared either by controlled cooling from the melt using a differential scanning calorimeter or by a conventional annealing procedure. Uniaxial stress effects in a range from 0 to −1.3 GPa were investigated in situ by compression of the glass cylinders. The spectroscopic observations of rearrangements in the network structure were related to the set cooling rates or the applied uniaxial stress to calculate an interrelated set of calibrations. Comparing the results from Raman and Brillouin spectroscopy with Nd3+ photoluminescence analysis, we find a linear dependence that can be used to identify uniaxial stress and cooling rate in any given combination concurrently. The interrelated calibrations and linear dependence models are established and evaluated, and equations relating the change of glass network due to effects of cooling rate or uniaxial stress are given.

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“…The absence of translational periodicity and symmetry, and the rich structural complexity make it difficult to understand the order within disorder 1 , 2 in disordered materials. The advent of advanced instrumentation and measurement protocols makes it feasible to use quantum beam diffraction (X-ray diffraction (XRD) and neutron diffraction (ND)) techniques to reveal the structure of disordered materials at synchrotron and/or neutron sources 3 – 6 .…”

Section: Introductionmentioning

confidence: 99%

Relationship between diffraction peak, network topology, and amorphous-forming ability in silicon and silica

Kohara

Shiga

Onodera

et al. 2021

Sci Rep

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The network topology in disordered materials is an important structural descriptor for understanding the nature of disorder that is usually hidden in pairwise correlations. Here, we compare the covalent network topology of liquid and solidified silicon (Si) with that of silica (SiO2) on the basis of the analyses of the ring size and cavity distributions and tetrahedral order. We discover that the ring size distributions in amorphous (a)-Si are narrower and the cavity volume ratio is smaller than those in a-SiO2, which is a signature of poor amorphous-forming ability in a-Si. Moreover, a significant difference is found between the liquid topology of Si and that of SiO2. These topological features, which are reflected in diffraction patterns, explain why silica is an amorphous former, whereas it is impossible to prepare bulk a-Si. We conclude that the tetrahedral corner-sharing network of AX2, in which A is a fourfold cation and X is a twofold anion, as indicated by the first sharp diffraction peak, is an important motif for the amorphous-forming ability that can rule out a-Si as an amorphous former. This concept is consistent with the fact that an elemental material cannot form a bulk amorphous phase using melt quenching technique.

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Structure and properties of densified silica glass: characterizing the order within disorder

Cited by 66 publications

References 50 publications

Structure of disordered materials under ambient to extreme conditions revealed by synchrotron x-ray diffraction techniques at SPring-8—recent instrumentation and synergic collaboration with modelling and topological analyses

Structure of disordered materials under ambient to extreme conditions revealed by synchrotron x-ray diffraction techniques at SPring-8—recent instrumentation and synergic collaboration with modelling and topological analyses

Coupling Raman, Brillouin and Nd3+ Photo Luminescence Spectroscopy to Distinguish the Effect of Uniaxial Stress from Cooling Rate on Soda–Lime Silicate Glass

Relationship between diffraction peak, network topology, and amorphous-forming ability in silicon and silica

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