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Regular version of the site
Of all publications in the section: 57
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Article
Павленко В. И., Бондаренко Г.Г., Черкашина Н. И. и др. Перспективные материалы. 2013. № 3. С. 14-19.

 In this paper it has been studied an effect of vacuum ultraviolet (VUV) irradiation at different temperatures on microstructure of polystyrene composites filled with organo-siloxane filler. It has been shown that the combined effects of vacuum and vacuum ultraviolet irradiation on the test materials result in a slight changes of surface layers. Irradiation at cryogenic temperature results cracks formed on the surface. It is suggested that the introduction of organo-siloxane filler lowers the operating temperature of the composite up to -170 º C, with damage to the surface layer of a thickness of 10 microns. Investigation of the evolution of the surface relief patterns has been performed. It has been shown a smoothing of the surface relief  under influence of VUV.

Added: Apr 3, 2013
Article
Артамонов А. В., Бондаренко Г. Г., Якункин М. М. Перспективные материалы. 2008. № 1. С. 83-87.
Added: Jan 4, 2013
Article
Андреев В. В., Бондаренко Г. Г., Столяров А. А. и др. Перспективные материалы. 2008. № 5. С. 26-30.
Added: Jan 4, 2013
Article
Дидык А. Ю., Ерискин А. А., Бондаренко Г. Г. и др. Перспективные материалы. 2015. № 9. С. 29-38.

The paper investigated the redistribution of hydrogen and deuterium in the assemblies of metallic foils Ta | CD2 | Ta, Ta | Ta | CD2 | Ta | Ta and Nb | CD2 | Nb, irradiated pulses of high-argon plasma at a plasma focus. Irradiated samples foils were investigated by detection of recoil nuclei of hydrogen and deuterium (ERDA). It found ultradeep penetration in the target light gas impurities (hydrogen and deuterium). It is assumed that this phenomenon is due to the influence of shock waves generated by a plasma pulse, and acceleration of diffusion processes.

Added: Aug 10, 2015
Article
Бондаренко Г.Г., Костина Е. П., Лапицкая В. Н. и др. Перспективные материалы. 2002. № 5. С. 68-70.
Added: Nov 29, 2013
Article
Бондаренко Г.Г., Андреев В. В., Барышев В. Г. и др. Перспективные материалы. 2000. № 3. С. 49-53.
Added: Nov 29, 2013
Article
Бондаренко Г. Г., Шагаев В. Перспективные материалы. 2011. № 5. С. 18-22.
Added: Mar 6, 2012
Article
Колокольцев В. Н., Михайлов Б. П., Иванов Л. И. и др. Перспективные материалы. 2011. № 5. С. 18-22.
Added: Apr 12, 2012
Article
Андреев В. В., Бондаренко Г. Г., Ахмелкин Д. М. и др. Перспективные материалы. 2017. № 10. С. 33-40.
Added: Oct 8, 2017
Article
Андреев В. В., Барышев В. Г., Бондаренко Г.Г. и др. Перспективные материалы. 1998. № 4. С. 61-65.
Added: Jan 27, 2014
Article
Ли И. П., Бондаренко Г. Г. Перспективные материалы. 2012. № 1. С. 30-34.

A method to improve emission homogeneity of pressed palladium–barium cathodes applied in magnetrons with self-heating initiation is proposed. The initial palladium powder is annealed at 950°C for 60 min and then calcined in vacuum under pressure of residual gases P ≤ 1 × 10–4 Pa. It is demonstrated that cathodes produced by pressing and subsequent sintering of a powdered mixture of palladium and intermetallic compound Pd5Ba in vacuum are characterized by a high distribution homogeneity of components. Within testing of magnetrons produced with such cathodes, the yield of good items is increased by a factor of 1.5.

Added: Nov 30, 2012
Article
Пименов В. Н., Демин А. С., Грибков В. А. и др. Перспективные материалы. 2014. № 10. С. 40-52.
Added: Oct 10, 2014
Article
Петров В. С., Бондаренко Г. Г., Васильевский В. В. и др. Перспективные материалы. 2005. № 6. С. 26-29.
Added: Jan 30, 2014
Article
Андреев В. В., Бондаренко Г. Г., Столяров А. А. и др. Перспективные материалы. 2009. № 2. С. 19-24.
Added: Oct 14, 2012
Article
Андреев В. В., Бондаренко Г.Г., Дегтярев В. Т. и др. Перспективные материалы. 2004. № 2. С. 20-27.
Added: Nov 25, 2013
Article
Бондаренко Г.Г., Удрис Я. Я., Акишин А. И. и др. Перспективные материалы. 2001. № 4. С. 54-58.
Added: Jan 28, 2014
Article
Жарков М. Ю., Боровицкая И. В., Люблинский И. Е. и др. Перспективные материалы. 2014. № 5. С. 27-33.

The corrosion resistance of vanadium alloys (V- 1,86Ga, V- 3,4Ga- 0,62 Si, V- 4,81Ti- 4,82Cr) in the liquid high purity lithium (carbon and nitrogen less than 1 • 10 -3 wt.%, oxygen ~ 0.02-0.03 wt.%)  in comparison with the pure vanadium has been studied. Corrosion tests were carried out in the static isothermal conditions at the temperature of 600 °C during 400 hours. It was established that vanadium and its alloys are practically insoluble when exposed to lithium,  oxygen transfer from  materials into the lithium being main mechanism of their interaction with the liquid metal in this case. Traces of corrosion effect on the surface morphology after exposure to lithium were also found, resulting in the appearance of grain boundaries and slip lines.The corrosion resistance of vanadium alloys (V- 1,86Ga, V- 3,4Ga- 0,62 Si, V- 4,81Ti- 4,82Cr) in the liquid high purity lithium (carbon and nitrogen less than 1 • 10 -3 wt.%, oxygen ~ 0.02-0.03 wt.%)  in comparison with the pure vanadium has been studied. Corrosion tests were carried out in the static isothermal conditions at the temperature of 600 °C during 400 hours. It was established that vanadium and its alloys are practically insoluble when exposed to lithium,  oxygen transfer from  materials into the lithium being main mechanism of their interaction with the liquid metal in this case. Traces of corrosion effect on the surface morphology after exposure to lithium were also found, resulting in the appearance of grain boundaries and slip lines.

Added: Oct 11, 2014