Adsorption capacity of water-oxidized lanthanum-doped aluminum alloy powder

The adsorption of nitrogen onto the surface of lanthanum-doped ultrafine aluminum (UFA) powder was studied before and after aqueous oxidation under relative adsorbate (Pa/Po) pressures from 0 to 1 using low-temperature nitrogen adsorption method in a volumetric static vacuum facility. The adsorption isotherms are considered for their compliance with the isotherms in the classification of S. Brunauer, L. Deming, U. Deming and E. Teller. The obtained results confirm that treatment of REM-containing powders with water leads already at room temperature to the formation of new phases and affects their morphology. It is shown that a large role in the properties of watertreated powders belongs to the nanopores formed between crystallites on the surface of particles in the process of oxidation with water and during subsequent thermal dehydration. The adsorption properties of Al – 3% La sample were examined by the following methods: analysis of adsorption-desorption isotherms of vapors (statistical volumetric method) based on nitrogen adsorption at 78 K, electron microscopic technique, and X-ray analysis. The specific surface area and porosity of the powders were calculated.

1. Kudryashov A.V., Dyagilets S.M., Andrianov N.T. Optimization of synthesis conditions of hydroxides and superfine alumina. Steklo i keramika, 4, P. 22–24 (2002). [in Russian]

2. Tikhov S.F., Romanenkov V.E., et al. Porous composites based on aluminum oxide cermets (synthesis and properties). Novosibirsk: Geo, 2004, 205 p. [in Russian]

3. Kozin L.F., Sakharenko V.A., Budarina A.N. Kinetics and mechanism of interaction of activated aluminum with water. Ukr. khim. zhurn., 50 (21), P. 161–169 (1984). [in Russian]

4. Kozin L.F., Sakharenko V.A. Kinetics and mechanism of interaction of aluminum, gallium and thallium based alloys with water. Ukr. khim. zhurn., 50, (1), P. 9–15 (1984).[in Russian]

5. Kozin L.F., Sarmurzina R.G. Study of the rate of interaction with water and the microstructure of aluminum gallium alloys. Zhurn. prikl. khim., 54 (310), P. 2176–2180 (1981). [in Russian]

6. Sarmurzina R.G., Sokolsky D.V., Kuralov G.G., Vozdvizhensky V.F. Physicochemical foundation of activation of aluminum for production of hydrogen fuel. Vopr. atomnoi nauki i tekhniki, ser. Atomnovodorodnaya energetika i technologiay, 2, P. 28–32 (1985). [in Russian]

7. Sarmurzina R.G. The kinetics of interaction of activated aluminum with water. Proc. of the Ist All-Union Symposium on microsc. kinetics and chem. gas dynamics. Alma-Ata, Chernogolovka, 1 (2), P. 24–25, 19–22 (1984). [in Russian]

8. Yatsenko S.P., Skachkov V.M., Shevchenko V.G. Production of hydrogen by decomposition of water with activated aluminum. Zh. prikl. khim., 84 (1), P. 35–38 (2011). [in Russian]

9. Ryabina A.V., Kononenko V.I., Razhabov A.A. Electrode-free method for measuring the electrical resistance of metals in solid and liquid states and an installation for its implementation. Rasplavy, 1, P. 36–42 (2009). [in Russian]

10. Ryabina A.V., Kononenko V.I., Seleznev A.S., Petrov L.A. Nitrogen adsorption on aluminum powders Al2O3 and AlN at 78 K. Zhurn. fizich. khimii, 88 (1), P. 134–137 (2014). [in Russian]

11. Shevchenko V.G., Malashin S.I. et al. The properties of finely dispersed Al-REM alloys produced by plasma recondensation. Perspektivnye materialy, 1, P. 68–75 (2010). [in Russian]

12. Greg S., Sing K. Adsorption. Specific surface. Porosity. Transl. from English. 2nd ed. Moscow: Mir, 1984. 306 pp. [in Russian]

13. Zhdanov V.P., Fenelonov V.B., Efremov D.K. J. Colloid Interface Sci., 120 (1). . 218 (1987).

14. Belyi A., Smolikov M.D., et al. The distribution of active componenet in the pores of different sizes in the structure of oxide carriers. Kinetika i kataliz, 27 (3), (1986). [in Russian]

15. Tolmachev A.M. Physico-chemical processes on interfaces. Adsorption of gases, vapors and solutions. II description and a priori calculations of adsorption equilibria. Fizikokhimiya poverkhnosti i zashchita materialov, 46 (3), P. 242–260 (2010). [in Russian]

16. Chalyi V.P. Metal hydroxides (Regularities of formation, composition, structure and properties). Naukova Dumka, Kiev, 1972. [in Russian]