Your search keyword '"Specific surface"' showing total 4 results

1. Impact sensitivity of energy systems based on nanoporous silicon and oxidant: influence of the hydrogen content and specific surface.

Author

Mikhailov, Yu., Garanin, V., Ganin, Yu., Goncharov, T., Ganina, L., and Zegrya, G.

Subjects

*NANOPOROUS materials, *SILICON oxidation, *SURFACE chemistry, *CALCIUM compounds, *ACTIVATION energy

Abstract

The impact sensitivity of the energy systems based on nanoporous silicon, obtained by electrochemical etching of monocrystalline silicon wafers in an HF-containing electrolyte, and calcium perchlorate was studied using a modified Weller-Ventselberg technique (estimation of the impact sensitivity of initiating explosives). The impact sensitivity of these systems is shown to be determined by both the presence of hydrogen, which is stored on the porous silicon surface during the preparation of the latter, and also the influence of other factors, including the specific surface of porous silicon. The composition, amount of the generated gas, and gas evolution rate during nonisothermal and isothermal calcination of porous silicon in a temperature range of 60-120 °С were determined using methods of thermal gravimetry (TG), measurement of the gas volume, and mass spectrometry. The generated gas almost completely consists of hydrogen, and its content in the studied samples of porous silicon achieved ~3.8 wt.%. The calculated activation energy of the hydrogen evolution process in vacuo was 103.7±3.3 kJ mol. The dependences of the impact sensitivity of the energy composition based on porous silicon and heat of combustion of porous silicon on oxygen on the hydrogen content were established. The impact sensitivity of the energy system decreases with a decrease in the hydrogen content in porous silicon and its specific surface. [ABSTRACT FROM AUTHOR]

Published

2016

2. Thermal decomposition of transition metal carboxylates.

Author

Rozenberg, A. and Aleksandrova, E.

Abstract

Thermal solid-phase decomposition of anhydrous copper( ii) formate has been studied at 120-180 ° The rate of gas evolution during the decomposition depends on the depth of conversion and can be presented as the sum of first-order reaction rates and the rate of the autocatalytic process (a second-order reaction). The evolution of the solid phase during thermolysis has been observed by optical microscopy. The decomposition of copper formate is a complex topochemical process, a combination of homogeneous and heterogeneous transformations and dispersion of large crystals. [ABSTRACT FROM AUTHOR]

Published

1996

3. Adsorption of water vapor on a non-porous carbon surface and evaluation of the mesopore surfaces of active carbons.

Author

Vartapetyan, R., Voloshchuk, A., Petukhova, G., and Polyakov, N.

Abstract

Adsorption of water vapor on non-porous carbon adsorbents (blacks) with different specific surfaces and a sufficiently high concentration of primary centers was studied. The maximum value of the adsorption is proportional to the surface and corresponds to the formation of (1.7±0.3) dense monomolecular layers. A method was proposed for determining the surface of non-porous carbon adsorbents and for evaluating the mesopore surfaces of active carbons. [ABSTRACT FROM AUTHOR]

Published

1993

4. Investigation of energetic heterogeneity of carbon black surfaces during adsorption of chromatographically low concentrations of n-pentane

Author

Yashkin, S. N. and Schuster, R. H.

Published

2003