High-pressure x-ray scattering and computer simulation studies of density-induced polyamorphism in silicon

Daisenberger, Dominik; Wilson, Mark; McMillan, Paul F.; Quesada-Cabrera, Raúl; Wilding, Martin C.; Machon, Denis

doi:10.1103/physrevb.75.224118

Cited by 90 publications

(110 citation statements)

References 65 publications

(103 reference statements)

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“…Such reversible transformations between LDA, HDA, and ph phases have also been observed for amorphous bulk Si (a-Si). [72][73][74] Theoretical investigations have attempted to characterize these amorphous phases in bulk Si [73][74][75][76][77][78] and hydrogenated Si nanocrystals. [20][21][22][23][24] The LDA phase has been described as a disordered tetrahedrally coordinated network, the HDA as a deformed tetrahedral network 75 with the presence of interstitials increasing the coordination to 5-6, and finally a veryhigh-density amorphous phase (VHDA) has been postulated 78 with coordinations 8-9 as found also in ice.…”

Section: Results: Pressure-induced Transformations In Silicon Nanmentioning

confidence: 99%

Simulations of nanocrystals under pressure: Combining electronic enthalpy and linear-scaling density-functional theory

Corsini

Greco

Hine

et al. 2013

The Journal of Chemical Physics

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We present an implementation in a linear-scaling density-functional theory code of an electronic enthalpy method, which has been found to be natural and efficient for the ab initio calculation of finite systems under hydrostatic pressure. Based on a definition of the system volume as that enclosed within an electronic density isosurface [M. Cococcioni, F. Mauri, G. Ceder, and N. Marzari, Phys. Rev. Lett. 94, 145501 (2005)], it supports both geometry optimizations and molecular dynamics simulations. We introduce an approach for calibrating the parameters defining the volume in the context of geometry optimizations and discuss their significance. Results in good agreement with simulations using explicit solvents are obtained, validating our approach. Size-dependent pressure-induced structural transformations and variations in the energy gap of hydrogenated silicon nanocrystals are investigated, including one comparable in size to recent experiments. A detailed analysis of the polyamorphic transformations reveals three types of amorphous structures and their persistence on depressurization is assessed.

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Section: Results: Pressure-induced Transformations In Silicon Nanmentioning

confidence: 99%

Simulations of nanocrystals under pressure: Combining electronic enthalpy and linear-scaling density-functional theory

Corsini

Greco

Hine

et al. 2013

The Journal of Chemical Physics

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“…multiple structures of amorphous materials with the same composition separated by a first order phase transition) remains a fundamentally important and unresolved phenomenon [408]. A wealth of indirect evidence for such transitions has already been established in H2O [407], SiO2 [200,409,410], GeO2 [61,224,411], Si [198,412,413], I [414], Se [414,415], S [415,416], P [197,417], Ce [406]. However, unambiguous evidence for liquid-liquid transition has yet to be presented in the liquid state for any system.…”

Section: Non-crystalline Materialsmentioning

confidence: 99%

High-pressure studies with x-rays using diamond anvil cells

2016

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Pressure profoundly alters all states of matter. The symbiotic development of ultrahighpressure diamond anvil cells, to compress samples to sustainable multi-megabar pressures; and synchrotron x-ray techniques, to probe materials' properties in situ, has enabled the exploration of rich high-pressure (HP) science. In this article, we first introduce the essential concept of diamond anvil cell technology, together with recent developments and its integration with other extreme environments. We then provide an overview of the latest developments in HP synchrotron techniques, their applications, and current problems, followed by a discussion of HP scientific studies using x-rays in the key multidisciplinary fields. These HP studies include: HP x-ray emission spectroscopy, which provides information on the filled electronic states of HP samples; HP x-ray Raman spectroscopy, which probes the HP chemical bonding changes of light elements; HP electronic inelastic x-ray scattering spectroscopy, which accesses high energy electronic phenomena, including electronic band structure, Fermi surface, excitons, plasmons, and their dispersions; HP resonant inelastic x-ray scattering spectroscopy, which probes shallow core excitations, multiplet structures, and spin-resolved electronic structure; HP nuclear resonant x-ray spectroscopy, which provides phonon densities of state and time-resolved Mössbauer information; HP x-ray imaging, which provides information on hierarchical structures, dynamic processes, and internal strains; HP x-ray diffraction, which determines the fundamental structures and densities of single-crystal, polycrystalline, nanocrystalline, and non-crystalline materials; and HP radial x-ray diffraction, which yields deviatoric, elastic and rheological information. Integrating these tools with hydrostatic or uniaxial pressure media, laser and resistive heating, and cryogenic cooling, has enabled investigations of the structural, vibrational, electronic, and magnetic properties of materials over a wide range of pressure-temperature conditions.

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“…Thus this discontinuity also supports occurrence of a transition. It is well known that the densities of amorphous solids and liquids scale like (Q 1 ) 3 in analogy with the diffraction in crystalline solids [22,23]. The Q 1 of the samples recovered from 17 GPa is found to be smaller than that for samples recovered from 33 GPa, suggesting that the two recovered amorphous phases have different densities.…”

Section: Resultsmentioning

confidence: 90%

Polyamorphism in network structures

Arora

2012

J. Phys.: Conf. Ser.

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Abstract. Reports of high-density amorphous forms of ice, quartz and Si have intensified the search for amorphous polymorphs in other systems. The network structures that exhibit pressure-induced amorphization are interesting from the point of view of polyamorphism. Recent in-situ high pressure Raman scattering and synchrotron x-ray diffraction studies on negative thermal expansion material zirconium tungstate have revealed an amorphous to amorphous transition at 19 GPa. The transition was identified for the discontinuities in the structural parameters such as position and height of the first peak of the structure factor and that in the tungstate internal vibrational mode frequency. Another compound, vanadium pentaoxide that forms a glass during melt-quenching, is also found to turn amorphous at 40 GPa, pointing to a possibility of polyamorphism.

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High-pressure x-ray scattering and computer simulation studies of density-induced polyamorphism in silicon

Cited by 90 publications

References 65 publications

Simulations of nanocrystals under pressure: Combining electronic enthalpy and linear-scaling density-functional theory

Simulations of nanocrystals under pressure: Combining electronic enthalpy and linear-scaling density-functional theory

High-pressure studies with x-rays using diamond anvil cells

Polyamorphism in network structures

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