The kinetics and mechanism of the interaction of aluminium and magnesium of the ternary system Al—Mg—Bi with water have been studies by hightemperature volumetry at high pressures and temperatures (225—325 ºC). The kinetic parameters of the reaction (rate constants, activation energies and degrees of transformation) have been calculated, and a mechanism of the corrosive dissolution of bismuth-activated aluminium and magnesium in water with hydrogen evolution at high rates is proposed. The phase composition of Al—Mg—Bi alloys has been determined by X-ray phase analysis; it has been shown that formation of the intermetallics Mg3Bi2 and Al3Mg2 is observed on its crystallization. The composition of the products of interaction between the ternary alloy Al—Mg—Bi and water (boekmite AlOOH and magnesium hydroxide Mg(OH)2) has been determined. The reaction proceeds with hydrogen evolution at a rate of 3196—4033 L/(m2min) in the temperature range in question. Microand nanoclusters in the form of globules, which consist of 5—12 Mg3Bi2 and Al3Mg2 nanoparticles, AlxBiy heteronanostructures (where x > y) and bismuth-activated aluminium aggregates, have been detected with the aid of a JSM6490 LV electron microscope (Japan).

The kinetics and mechanism of interaction between bismuth- and gallium-activated aluminium and water in a temperature range of 150—325 ºС have been studied by high-temperature high-pressure volumetry. The kinetic parameters of the reaction have been calculated, and a mechanism of corrosive dissolution of galliumor bismuth-activated aluminium with hydrogen evolution from water is proposed. Kinetic parameters (rate constants, activation energies and degrees of transformation) in the case of interaction between gallium- or bismuth-activated aluminium and water by the reaction of water oxidation of aluminium to boehmite with hydrogen evolution of a rate of 987—2600 L/(m2min) have been determined. Nanostructured Al—Bi alloy particles have been detected with the aid of a ZEISS EVO 50 XVP electron microscope.

Kinetic parameters: rate constants and activation energies of corrosive dissolution of bismuthactivated aluminium in water in a temperature range of 250—325 ºС have been determined. A mechanism of dissolution of proposed. The microstructure of bismuth-activated aluminium has been determined with the aid of a ZEISS EVO 50XVP scanning electron microscope; the presence of bismuth nanoparticles and bismuth-aluminium alloy globules in the aluminium-bismuth matrix has been established.