Lonsdaleite is faulted and twinned cubic diamond and does not exist as a discrete material

Németh, Péter; Garvie, L. A. J.; Aoki, Toshihiro; Dubrovinskaia, Natalia; Dubrovinsky, Leonid; Buseck, Peter R.

doi:10.1038/ncomms6447

Cited by 221 publications

(223 citation statements)

References 37 publications

(84 reference statements)

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“…It has long been known [1] that at ambient conditions graphite is the thermodynamically most stable carbon allotrope and that many structural transformations and modifications of carbon structures in various sp 2 and sp 3 bonding networks can be produced under various pressure and temperature conditions. Under high static pressure and high temperature conditions, graphite can be converted to cubic diamond [2][3][4][5][6] or twinned cubic diamond with {111} hexagonal-diamond-like stacking faults [5,6]; meanwhile, under cold static compression graphite can transform to diamond-like sp 3 carbon forms [7][8][9][10][11][12][13][14]. Additional cubic modifications of carbon have been produced during the heating of carbon soot or shock compression of polycrystalline graphite [15][16][17][18], which led to a proposed simple cubic carbon phase termed SC24 in P a3 symmetry [19] and a body-centered cubic carbon phase termed BC12 in Ia3d symmetry [20].…”

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confidence: 99%

Body-Centered OrthorhombicC16: A Novel Topological Node-Line Semimetal

et al. 2016

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confidence: 99%

Body-Centered OrthorhombicC16: A Novel Topological Node-Line Semimetal

et al. 2016

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“…They 86 observed the {113} twins and/or {111} stacking faults over a 2 nm scale by using ultra-high resolution electron microscope images. 86 Their findings seems intriguing because the density of Lonsdaleite is 3.2-3.52 g/cm 3 , [http://www.handbookofmineralogy.com/ pdfs/lonsdaleite.pdf], which is comparable to the measurable density of 3.514 g/cm 3 of (cubic) diamond. (Theoretical density of Lonsdaleite is 3.51 g/cm 3 , which is the same as the measured density of 3.514 g/cm 3 of cubic diamond.…”

Section: General Aspects Of Stacking Disorder In Interlaced Ice Icmentioning

confidence: 72%

“…It remains to be investigated if the requirement that two crystal lattices have the same density and nearly the same energy to form stacking faults can be fulfilled by some structures formed by carbon atoms alone. We also note a recent finding that twinning and/or stacking faults may be present 86 in meteoritic-impact shock wave-produced (and also laboratory-produced) hexagonal diamond known as Lonsdaleite. They 86 observed the {113} twins and/or {111} stacking faults over a 2 nm scale by using ultra-high resolution electron microscope images.…”

Section: General Aspects Of Stacking Disorder In Interlaced Ice Icmentioning

confidence: 99%

Effects of stacking disorder on thermal conductivity of cubic ice

Johari

Andersson

2015

The Journal of Chemical Physics

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This is the published version of a paper published in J. Chem. Phys. Citation for the original published paper (version of record):Johari,G.P., Andersson, O. (2015) Effects of stacking disorder on thermal conductivity of cubic ice J. Chem. Phys., 143, 054505 (2015).Access to the published version may require subscription. N.B. When citing this work, cite the original published paper. Cubic ice is said to have stacking disorder when the H 2 O sequences in its structure (space group Fd3m) are interlaced with hexagonal ice (space group P6 3 /mmc) sequences, known as stacking faults. Diffraction methods have shown that the extent of this disorder varies in samples made by different methods, thermal history, and the temperature T, but other physical properties of cubic and hexagonal ices barely differ. We had found that at 160 K, the thermal conductivity, κ, of cubic ice is ∼20% less than that of hexagonal ice, and this difference varies for cubic ice samples prepared by different methods and/or subjected to different thermal history. After reviewing the methods of forming cubic ice, we report an investigation of the effects of stacking disorder and other features by using new data, and by analyzing our previous data on the dependence of κ on T and on the pressure. We conclude that the lower κ of cubic ice and its weaker T-dependence is due mainly to stacking disorder and small crystal sizes. On in situ heating at 20-50 MPa pressure, κ increases and cubic ice irreversibly transforms more sharply to ice Ih, and at a higher T of ∼220 K, than it does in ex situ studies. Cooling and heating between 115 and 130 K at 0.1 K min −1 rate yield the same κ value, indicating that the state of cubic ice in these conditions does not change with time and T. The increase in κ of cubic ice observed on heat-annealing before its conversion to hexagonal ice is attributed to the loss of stacking faults and other types of disorders, and to grain growth. After discussing the consequences of our findings on other properties, we suggest that detailed studies of variation of a given property of cubic ice with the fraction of stacking faults in its structure may reveal more about the effect of this disorder. A similar disorder may occur in the mono-layers of H 2 O adsorbed on a substrate, in bulk materials comprised of two dimensional layers, in diamond and in Zirconium and in numerous other crystals. C 2015 AIP Publishing LLC. [http://dx

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“…The energy difference between lonsdaleite and diamond is less than 10 meV per bond (it is significantly less than the 20 meV per atom difference between diamond and graphite), so for practical purposes, it can be neglected. There is even a tendency to regard lonsdaleite as a diamond structure, but with a considerable number of stacking faults [23]. In a more formal way, this procedure can be described as a virtual symmetry breaking operation so the equivalence of lattice nodes in diamond (space group F d3m, single Wyckoff position 8a) and lonsdaleite (P 6 3 /mmc, 4f ) structures aren't retained and their occupancies may vary 1 .…”

Section: The Least Strained Structuresmentioning

confidence: 99%

Is graphane the most stable carbon monohydride?

Kondrin

Бражкин²

2016

Nanosystems: Phys. Chem. Math.

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We discuss a number of hydrocarbon structures whose cohesive energy is not worse than that of benzene and graphanes. These structures can be regarded as sublattices of known carbon structures so the strain exerted on the crystal lattice is minimal and caused mostly by the steric interactions of hydrogen atoms. Possible synthetic routes are proposed. Due to their exceptional mechanical, structural and electrical properties, these crystal structures may have utility as mechanical, optoelectronic or biological materials.

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Lonsdaleite is faulted and twinned cubic diamond and does not exist as a discrete material

Cited by 221 publications

References 37 publications

Body-Centered OrthorhombicC16: A Novel Topological Node-Line Semimetal

Body-Centered OrthorhombicC16: A Novel Topological Node-Line Semimetal

Effects of stacking disorder on thermal conductivity of cubic ice

Is graphane the most stable carbon monohydride?

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