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Dutta, Rajkrishna; White, Claire E.; Greenberg, Eran; Prakapenka, Vitali B.; Duffy, Thomas S.

doi:10.1103/physrevb.98.144106

Cited by 8 publications

(9 citation statements)

References 78 publications

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“…This simple comparison of the pressure dependence of the Ge-O distance evidences that there is a strong difference in the compressional behavior of the Ge coordination polyhedron between NaAlGe 3 O 8 and GeO 2 glass. The weaker shortening of the Ge-O bond distance beyond 110 GPa in NaAlGe 3 O 8 might indicate the onset of polyhedral distortions similar to those observed for GeO 2 in the α-PbO 2 structure [43].…”

Section: Discussionmentioning

confidence: 66%

Ge coordination inNaAlGe3O8glass upon compression to 131 GPa

et al. 2020

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Structural transformations at high pressure in NaAlGe 3 O 8 glass were investigated by means of x-ray absorption spectroscopy at the Ge K edge in combination with a diamond anvil cell. The obtained results provide a detailed picture of the local structural behavior of Ge in a chemically complex glass under compression. First and second shell bond distances (R Ge-O and R Ge...Ge ) were extracted assuming contributions of two scattering paths (Ge-O and Ge …Ge). We observed a significant extension of the Ge-O distance from 1.73 to 1.82 Å between 3 and ∼26 GPa, accompanied by an increase of the fitted number of nearest neighbors from ∼4 to ∼6. These observations can be attributed to the change from tetrahedral to octahedral Ge coordination. Second shell bond distances Ge …Ge are also consistent with this structural transformation. Between 34 and 131 GPa, the evolution of the fitted Ge-O distance implies a gradual volume reduction of the Ge octahedra. At the highest probed pressure of 131 GPa a Ge-O distance of 1.73 Å was found, which is similar to the one obtained at ambient conditions for Ge in fourfold coordination. The compressibility of the Ge-O octahedron in NaAlGe 3 O 8 beyond 34 GPa is considerably higher than the one reported for amorphous GeO 2 from x-ray diffraction analysis but it is similar to the one reported for the Ge octahedron in crystalline rutile-type GeO 2 . We attribute the high compressibility of the Ge-O bond in NaAlGe 3 O 8 glass to the presence of Al and Na that increase the system's complexity and therefore its degrees of freedom. Beyond 110 GPa the data on NaAlGe 3 O 8 glass indicate the onset of polyhedral distortion. The performed study provides insights into the structural changes of complex and polymerized germanate glasses or melts at extreme pressure conditions.

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Section: Discussionmentioning

confidence: 66%

Ge coordination inNaAlGe3O8glass upon compression to 131 GPa

et al. 2020

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“…2). At such pressure the material has a high bulk modulus of about 300 GPa, derived from our third-order BM fit (V 0 = 15.39(1.5) cm −3 /mol, K 0 = 304 (8) GPa and K 0 = 4, Table S2; see Supplemental Material [44]), almost similar to the one of the crystalline GeO 2 in the pyrite structure, with K 0 = 347 (12) GPa (K 0 = 4) [1] and also equivalent to the one of the α-PbO 2 structure with K 0 = 292 (10) GPa (K 0 = 4). At higher pressure, the propagated values for the bulk modulus will also be comparable between the crystalline and amorphous phases, because of the similarity in the parameters for the EOS (same K values).…”

Section: Results and Comparison With Previous Reportsmentioning

confidence: 85%

“…Our density data as a function of pressure (Table S1; see Supplemental Material [44]) are reported in Fig. 2 and compared with previous measurements carried out using the x-ray absorption method [11], tomography imaging [46], or AIMD calculation [41], as well as with the density of the crystalline high-pressure GeO 2 polymorphs [1]. The compressibility of GeO 2 can be analyzed using a finite strain plot in the Vinet form [47], or f -F plot, to reveal the different pressure domains of dominant coordination species for which individual equations of state can be derived, as it was shown for the compressed amorphous SiO 2 [20].…”

Section: Results and Comparison With Previous Reportsmentioning

confidence: 88%

“…SiO 2 is the most abundant component in naturally occurring silicate melts on Earth and other telluric planetary bodies. GeO 2 is a structural analog to SiO 2 , being a network former in the amorphous state at ambient pressures and exhibiting a similar succession of crystalline high-pressure structures and transitions, with minor differences only at low pressure [1][2][3][4][5][6]. At ambient conditions, the structure of both oxides consists of an infinitely extended network of SiO 4 4− and GeO 4 4− tetrahedra, respectively.…”

Section: Introductionmentioning

confidence: 99%

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Density of amorphous GeO2 to 133 GPa with possible pyritelike structure and stiffness at high pressure

et al. 2019

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Germanium oxide is a prototype network-forming oxide with pressure-induced structural changes similar to those found in crystals and amorphous silicate oxides at high pressure. Studying density and coordination changes in amorphous GeO 2 allows for insight into structural changes in silicate oxides at very high pressure, with implications for the properties of planetary magmas. Here, we report the density of germanium oxide glass up to 133 GPa using the x-ray absorption technique, with very good agreement with previous experimental data at pressure below 40 GPa and recent calculation up to 140 GPa. Our data highlight four distinct compressibility domains, corresponding to changes of the local structure of GeO 2. Above 80 GPa, our density data show a compressibility and bulk modulus similar to the counterpart crystal phase, and we propose that a compact distorted sixfold coordination, similar to the structural motif of the pyritelike crystalline GeO 2 polymorph, is likely to be stable in that pressure range. Our density data point to a smooth continuous evolution of the average coordination for pressure above 20 GPa with persistent sixfold coordination, without sharp density or density slope discontinuities. These observations are in very good agreement with theoretical calculations and spectroscopic measurements, and our results indicate that glasses and melts may behave similarly to their high-pressure solid counterparts with comparable densities, compressibility, and possibly average coordination.

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“…GeO 2 glass is of particular interest because the local structure of Ge atoms at high pressure can be determined by x-ray absorption fine structure (XAFS) technique in diamond anvil cell (DAC). The pressure-induced local structural changes of GeO 2 glass have been extensively studied using x-ray-absorption spectroscopy [7][8][9][10], x-ray diffraction (XRD) [11][12][13][14][15][16], neutron diffraction (ND) [17][18][19][20][21], inelastic x-ray scattering [22,23], x-ray Raman scattering at the oxygen K-edge [24,25], x-ray emission spectroscopy [26], and a number of theoretical studies such as classical [27][28][29] and first-principles molecular dynamics simulations [30][31][32]. Important structural and spectroscopic details on the local short-range order (SRO) and the intermediate-range order (IRO) of GeO 2 glass under compression have been successfully revealed [3,6,18,33].…”

Section: Introductionmentioning

confidence: 99%

Local structural investigation of non-crystalline materials at high pressure: the case of GeO₂ glass

Hong

Newville

Ding

2023

J. Phys.: Condens. Matter

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Local structures play a crucial role in the structural polyamorphism and novel electronic properties of amorphous materials, but their accurate measurement at high pressure remains a formidable challenge. In this article, we use the local structure of network-forming GeO2 glass as an example, to present our recent approaches and advances in high-energy X-ray diffraction, high-pressure XAFS, and ab initio first-principles DFT calculations and simulations. Although GeO2 glass is one of the best studied materials in the field of high pressure research due to its importance in glass theory and geophysical significance, there are still some long-standing puzzles, such as the existence of appreciable distinct fivefold [5]Ge coordination at low pressure and the sixfold-plus [6+]Ge coordination at ultrahigh pressure. Our work sheds light on the origin of pressure-induced polyamorphism of GeO2 glass, and the [5]Ge polyhedral units may be the dominant species in the densification mechanism of network-forming glasses from tetrahedral to octahedral amorphous structures.

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Equation of state of theα−PbO2andPa3¯-type phases of
Rajkrishna Dutta
¹
,
Claire E. White
²
,
Eran Greenberg
³

et al.

Cited by 8 publications

References 78 publications

Ge coordination inNaAlGe3O8glass upon compression to 131 GPa

Ge coordination inNaAlGe3O8glass upon compression to 131 GPa

Density of amorphous GeO2 to 133 GPa with possible pyritelike structure and stiffness at high pressure

Local structural investigation of non-crystalline materials at high pressure: the case of GeO₂ glass

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Equation of state of theα−PbO2andPa3¯-type phases ofRajkrishna Dutta1, Claire E. White2, Eran Greenberg3 et al.

Cited by 8 publications

References 78 publications

Ge coordination inNaAlGe3O8glass upon compression to 131 GPa

Ge coordination inNaAlGe3O8glass upon compression to 131 GPa

Density of amorphous GeO2 to 133 GPa with possible pyritelike structure and stiffness at high pressure

Local structural investigation of non-crystalline materials at high pressure: the case of GeO2 glass

Contact Info

Product

Resources

About

Equation of state of theα−PbO2andPa3¯-type phases of
Rajkrishna Dutta
¹
,
Claire E. White
²
,
Eran Greenberg
³

et al.

Local structural investigation of non-crystalline materials at high pressure: the case of GeO₂ glass