Eun Jeong Kim scite author profile

The detailed degree of mixing between framework Si and metal cations and the nature of oxygen that only links metal cations (metal-bridging oxygen) in archetypal metal oxide glasses have been among the unsolved problems in physical chemistry. Binary lead silicate (PbO-SiO2) glass is an ideal model system for exploring the extent of cation disorder and metal-bridging oxygen because of its peculiar glass-forming ability at high PbO concentration. Here we report the first high-resolution 17O solid-state NMR spectra for binary lead silicate glasses with varying composition (near that of orthosilicate, i.e., Pb/Si = 2), where peaks due to metal-bridging oxygen (Pb-O-Pb), as well as Pb-O-Si and Si-O-Si are clearly resolved. The spectra also reveals that the metal-bridging oxygen possesses a greater topological disorder due to structural complexity in Pb coordination environments. Together with a statistical thermodynamic model of oxygen speciation proposed to describe mixing behavior in oxide glasses with any oxygen coordination number, the current 17O NMR results allow direct quantification of the degree of Pb/Si disorder and estimation of relative energy difference among the oxygen clusters [Pb-O-Pb + Si-O-Si = 2(Pb-O-Si)] of ∼−6 kJ/mol. This corresponds to a degree of mixing (Q) between Pb and network Si of ∼0.9, which implies that it deviates from random distribution (Q = 0) but shows a tendency toward Pb/Si order (Q = 1) that favors the formation of the Pb-O-Si cluster. The calculated configurational enthalpy of lead silicate glasses based on 17O NMR data showed a negative deviation and is consistent with those estimated from experimental solution calorimetry, unveiling atomistic origins of bulk macroscopic properties in the amorphous oxide. The results and methods shed light on a unique opportunity to explore the nature of intermixing and topological disorder in diverse complex amorphous oxides with varying cation types and oxygen coordination numbers by estimating the exact proportion of metal-bridging oxygen.

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Quasi-equilibrium melting of quartzite upon extreme friction

Lee

Han

Kim

et al. 2017

Nature Geosci

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Depressed 660-km discontinuity caused by akimotoite–bridgmanite transition

Chanyshev

Ishii

Bondar

et al. 2022

Nature

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The 660-kilometre seismic discontinuity is the boundary between the Earth’s lower mantle and transition zone and is commonly interpreted as being due to the dissociation of ringwoodite to bridgmanite plus ferropericlase (post-spinel transition)1–3. A distinct feature of the 660-kilometre discontinuity is its depression to 750 kilometres beneath subduction zones4–10. However, in situ X-ray diffraction studies using multi-anvil techniques have demonstrated negative but gentle Clapeyron slopes (that is, the ratio between pressure and temperature changes) of the post-spinel transition that do not allow a significant depression11–13. On the other hand, conventional high-pressure experiments face difficulties in accurate phase identification due to inevitable pressure changes during heating and the persistent presence of metastable phases1,3. Here we determine the post-spinel and akimotoite–bridgmanite transition boundaries by multi-anvil experiments using in situ X-ray diffraction, with the boundaries strictly based on the definition of phase equilibrium. The post-spinel boundary has almost no temperature dependence, whereas the akimotoite–bridgmanite transition has a very steep negative boundary slope at temperatures lower than ambient mantle geotherms. The large depressions of the 660-kilometre discontinuity in cold subduction zones are thus interpreted as the akimotoite–bridgmanite transition. The steep negative boundary of the akimotoite–bridgmanite transition will cause slab stagnation (a stalling of the slab’s descent) due to significant upward buoyancy14,15.

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Effect of pressure on the short-range structure and speciation of carbon in alkali silicate and aluminosilicate glasses and melts at high pressure up to 8 GPa: 13C, 27Al, 17O and 29Si solid-state NMR study

Kim

Fei

Lee

2018

Geochimica et Cosmochimica Acta

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Eun Jeong Kim

Probing Metal-Bridging Oxygen and Configurational Disorder in Amorphous Lead Silicates: Insights from ¹⁷O Solid-State Nuclear Magnetic Resonance

Quasi-equilibrium melting of quartzite upon extreme friction

Depressed 660-km discontinuity caused by akimotoite–bridgmanite transition

Effect of pressure on the short-range structure and speciation of carbon in alkali silicate and aluminosilicate glasses and melts at high pressure up to 8 GPa: 13C, 27Al, 17O and 29Si solid-state NMR study

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Eun Jeong Kim

Probing Metal-Bridging Oxygen and Configurational Disorder in Amorphous Lead Silicates: Insights from 17O Solid-State Nuclear Magnetic Resonance

Quasi-equilibrium melting of quartzite upon extreme friction

Depressed 660-km discontinuity caused by akimotoite–bridgmanite transition

Effect of pressure on the short-range structure and speciation of carbon in alkali silicate and aluminosilicate glasses and melts at high pressure up to 8 GPa: 13C, 27Al, 17O and 29Si solid-state NMR study

Contact Info

Product

Resources

About

Probing Metal-Bridging Oxygen and Configurational Disorder in Amorphous Lead Silicates: Insights from ¹⁷O Solid-State Nuclear Magnetic Resonance

Effect of pressure on the short-range structure and speciation of carbon in alkali silicate and aluminosilicate glasses and melts at high pressure up to 8 GPa: 13C, 27Al, 17O and 29Si solid-state NMR study