Aggregated diamond nanorods, the densest and least compressible form of carbon

Dubrovinskaia, Natalia; Dubrovinsky, Leonid; Crichton, Wilson A.; Langenhorst, F.; Richter, Asta

doi:10.1063/1.2034101

Cited by 101 publications

(75 citation statements)

References 19 publications

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“…Hence, any data obtained for small-sized, poorly crystallized samples have to be considered invalid. For example, the statement that a diamond nanorods composite has the bulk modulus B ~ 490 GPa, which is 11% greater than the value for diamond [45], is obviously untrue. Undoubtedly erroneous is information on record high bulk moduli of carbon phases obtained from fullerite C 60 : B ~1000 -1600 GPa [46].…”

Section: Superhard Materials: More Equal Than Othersmentioning

confidence: 99%

High-pressure synthesized materials: treasures and hints

Бражкин

2007

High Pressure Research

108

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The present review covers the production of new materials under high pressures. A primary limitation on the use of pressures higher than 1 GPa is a small volume and mass of a produced material. Therefore, despite an extremely wide range of new high-pressure synthesized substances with unique properties, synthesis on an commercial scale is applied up to now only to obtain superhard materials, this real treasure of today's industry. At the same time, high-pressure experiments often give material scientists a hint at what new intriguing substances can exist in principle. This is true for new superhard, semiconducting, magnetic, superconducting and optical materials already synthesized under pressure, and as well as for a large number of hypothetic new polymers from low-Z elements. Many of new materials, including the above polymers, may exist in the metastable form at normal pressure at sufficiently high temperatures.Keywords: high pressure, materials synthesis, metastable phases 1 IntroductionThe synthesis of materials under high pressure is a vast area of physics, chemistry and engineering. Should you browse the Internet to search "high pressure synthesis", the web search engines, for example, Google, would respond with over 10 mln links, making it absolutely impossible to write any comprehensive review on this topic. For this same reason, neither it is possible to list all relevant references. The purpose of this paper is to present the author's personal view on the state of art and prospects of the production of new materials by using highpressure synthesis, and to complement already existing reviews, for example [1,2]. It should be noted that a number of publications, for example [2], discuss a comparatively narrow range of materials synthesized under pressure. Other publications, for example [1], also focus on anomalous properties of materials in a strongly compressed state, although most of materials with such properties cannot be retained at normal pressure, hence, they are not directly related to the subject under consideration. In addition, the behavior of materials in a strongly compressed state has also been extensively covered in scientific literature (for example, see [3]).For physicists, the history of a high-pressure research is first of all associated with P.W. Bridgman, a 1946 Nobel Prize Laureate "for the invention of an apparatus to produce extremely high pressures, and for the discoveries he made therewith in the field of high pressure physics". Nowadays high-pressure synthesis of new materials is primarily associated with a successful synthesis of superhard materials -diamond and cubic boron nitride -in the second half of the 20 th century. At the same time, the pressures 1 -10 3 MPa have been already in use for more than a century in chemistry for the industrial production of materials. What's more, the development of relevant engineering procedures has been more than once rewarded with a Nobel Prize in chemistry. In 1918, F. Haber won the Nobel Prize "for the synthesis of ammonia from its el...

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Section: Superhard Materials: More Equal Than Othersmentioning

confidence: 99%

High-pressure synthesized materials: treasures and hints

Бражкин

2007

High Pressure Research

108

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“…[19,20] We found that, for the high frequency broad band, the most intense peak is at 1470 cm -1 when excited by an 830 nm laser, while it becomes 1540 cm -1 when using 514 nm excitation. From in situ high pressure Raman measurements, we can clearly see that the two bands at 1470 cm -1 and 1540 cm -1 evolve from the H g (7) and H g (8) modes, respectively. This is important evidence for the preservation of fullerenes or fullerenelike fragments, consisting of hexagonal and pentagonal carbon rings, in the high pressure phase and in the quenched sample released from 44 GPa.…”

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confidence: 99%

“…Thanks to the strong C-C covalent bonds, many carbon phases, including both crystalline and noncrystalline forms, are found to exhibit high hardness and have important technological applications in different fields. The structures and the formation mechanisms of hard carbon phases thus have been subjected to numerous experimental [1][2][3][4][5][6][7][8][9] and theoretical [10,11] works.…”

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confidence: 99%

Pressure-induced transformation and superhard phase in fullerenes: The effect of solvent intercalation

Yao

Cui

Xiao

et al. 2013

Applied Physics Letters

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Pressure-induced transformation and superhard phase in fullerenes: the effect of solvent intercalation.Applied Physics Letters, 103 (7) Abstract:We studied the behavior of solvated and desolvated C 60 crystals under pressure by in situ Raman spectroscopy. The pressure-induced bonding change and structural transformation of C 60 s are similar in the two samples, both undergoing deformation and amorphization.Nevertheless, the high pressure phases of solvated C 60 can indent diamond anvils while that of desolvated C 60 s cannot. Further experiments suggest that the solvents in the solvated C 60 act as both spacers and bridges by forming covalent bonds with neighbors in 3D network at high pressure, and thus, a fraction of fullerenes may preserve the periodic arrangement in spite of their amorphization.

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“…1 Moreover, in the past few years, it has been possible to produce materials with very small diamond crystals, with particle sizes in the order of a few nm. 2 Indeed, the synthesis of nanocrystalline films of diamondlike carbon, polycrystalline cubic diamond, and aggregated diamond nanorods has been reported in literature [3][4][5][6][7][8][9] Importantly, polycrystalline diamond, reported to consist of very fine granular crystals, was found to be as hard or even harder than single-crystal diamond, with constant hardness throughout the sample. 3 The aggregated diamond nanorods, and mesoporous diamond composed of interconnected nanocrystals, were found to be the densest among all carbon materials and had the lowest experimentally determined compressibility.…”

Section: Introductionmentioning

confidence: 99%

“…3 The aggregated diamond nanorods, and mesoporous diamond composed of interconnected nanocrystals, were found to be the densest among all carbon materials and had the lowest experimentally determined compressibility. 8 In such polycrystalline aggregates, the amount of substance located in between the crystallites, i.e., in the grain boundary (GB), becomes considerably larger and hence very important for the material properties. Diamond GBs have therefore been studied extensively, both experimentally 2 and theoretically, [10][11][12] with substantial attention given to the determination of their chemical bonding.…”

Section: Introductionmentioning

confidence: 99%

Missing-atom structure of diamondΣ5 (001) twist grain boundary

et al. 2011

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We carried out a combined experimental and theoretical study of grain boundaries in polycrystalline diamond, aimed at achieving the conditions in which grain boundaries are equilibrated. Raman spectra of compacted at high-pressure and high-temperature diamond powders allow us to identify signals from sp 2 -bonded atoms, in addition to a strong peak at 1332 cm −1 , corresponding to sp 3 -bonded carbon. To verify our interpretation of the experiment, 5 (001) twist grain boundaries of polycrystalline diamond were studied by means of molecular dynamics simulations using the technique proposed by von Alfthan et al. [Phys. Rev. Lett. 96, 055505 (2006)]. We find that grain-boundary (GB) configurations, from which one atom is removed, have significantly lower energy compared to those obtained with conventional techniques. These calculated GBs are highly ordered, a few monolayers thick, in agreement with experimental observations, and are primarily sp 2 bonded. This paper underlines the importance of varying the number of atoms within GBs in molecular dynamics simulations to correctly predict the GB ground-state structure.

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Aggregated diamond nanorods, the densest and least compressible form of carbon

Cited by 101 publications

References 19 publications

High-pressure synthesized materials: treasures and hints

High-pressure synthesized materials: treasures and hints

Pressure-induced transformation and superhard phase in fullerenes: The effect of solvent intercalation

Missing-atom structure of diamondΣ5 (001) twist grain boundary

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