Nanocarbon Phase Diagram and Conditions for Detonation Nanodiamond Formation

Даниленко, В. В.

doi:10.1007/1-4020-3322-2_14

Cited by 8 publications

(13 citation statements)

References 4 publications

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“…For example, according to (9), for a typical size of 4 nm, it is only 7% lower than that for a single crystal. In the diamond stability region in the phase diagram of carbon, there is a region of liquid nanocarbon sp 3 (or liquid nanodiamond) whose lower pressure boundary is the line of the family of triple points located in the interval of 13.5-16.5 GPa [8,9]. In the same region there are the detonation pressures and temperatures of powerful explosive compositions used for the synthesis of detonation nanodiamonds.…”

Section: Melting Of Detonation Nanodiamondsmentioning

confidence: 96%

“…For detonation nanodiamonds, we obtained the following simple dependence of the melting point of nanodiamonds T d on the particle size d [8,9]:…”

Section: Melting Of Detonation Nanodiamondsmentioning

confidence: 99%

“…4. Position of the family of triple points and melting curves of nanodiamonds [8,9]: open points show the position of triple points according to [24,25], dashed curves are curves of the phase diagram of carbon; the numbers at the curves denote the particle size, nm. nanodiamonds are formed by crystallization of nanosized droplets behind the detonation-wave front [9,22,23].…”

Section: Melting Of Detonation Nanodiamondsmentioning

confidence: 99%

“…Due to the effect of surface energy, the calculated temperature of their melting decreases considerably [8,9], which increases the chances to melt nanodiamonds in experiments.…”

Section: Introductionmentioning

confidence: 97%

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Shock-induced melting of diamond powders

Даниленко¹

2009

Combust Explos Shock Waves

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Conditions of shock-induced melting of diamond powders are considered. For powders of various porosities, shock Hugoniots in the coordinates (p, u) and (p, T ) and the pressures at the beginning and end of equilibrium melting are calculated. Thermal nonequilibrium of the shock compression of the powders is analyzed. Pressures at the onset of melting near pores are calculated. Shock-induced melting of detonation nanodiamond powders is considered. Calculation results show that explosion-induced melting of diamond powders is possible only under energy cumulation conditions.

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Section: Melting Of Detonation Nanodiamondsmentioning

confidence: 96%

“…For detonation nanodiamonds, we obtained the following simple dependence of the melting point of nanodiamonds T d on the particle size d [8,9]:…”

Section: Melting Of Detonation Nanodiamondsmentioning

confidence: 99%

Section: Melting Of Detonation Nanodiamondsmentioning

confidence: 99%

“…Due to the effect of surface energy, the calculated temperature of their melting decreases considerably [8,9], which increases the chances to melt nanodiamonds in experiments.…”

Section: Introductionmentioning

confidence: 97%

See 2 more Smart Citations

Shock-induced melting of diamond powders

Даниленко¹

2009

Combust Explos Shock Waves

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“…Both models of phase transition, where the diamond is formed during the detonation wave, 56 and chemical pathway, where the detonation wave forms the chemical precursors necessary for diamond growth, 18 have been suggested. For chemical growth mechanisms, temperatures of less than 1000 K and pressures between 1 kPa and 100 kPa are required.…”

mentioning

confidence: 99%

Diamond-like-carbon nanoparticle production and agglomeration following UV multi-photon excitation of static naphthalene/helium gas mixtures

Walsh

Tielens

Ruth

2016

The Journal of Chemical Physics

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We report the formation of nanoparticles with significant diamond character after UV multi-photon laser excitation of gaseous naphthalene, buffered in static helium gas, at room temperature. The nanoparticles are identified in situ by their absorption and scattering spectra between 400 and 850 nm, which are modeled using Mie theory. Comparisons of the particles’ spectroscopic and optical properties with those of carbonaceous materials indicate a sp3/sp2 hybridization ratio of 8:1 of the particles formed. The particle extinction in the closed static (unstirred) gas-phase system exhibits a complex and quasi-oscillatory time dependence for the duration of up to several hours with periods ranging from seconds to many minutes. The extinction dynamics of the system is based on a combination of transport features and particle interaction, predominantly agglomeration. The relatively long period of agglomeration allows for a unique analysis of the agglomeration process of diamond-like carbon nanoparticles in situ.

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