Metastable colloidal states of liquid metallic solutions / Popel PS,Chikova OA,Matveev VM // HIGH TEMPERATURE MATERIALS AND PROCESSES. - 1995. - V. 14, l. 4. - P. 219-233.

ISSN/EISSN:
0334-6455 / нет данных
Type:
Article
Abstract:
Branching of curves produced during the heating and subsequent cooling process after sample melting was observed while investigating the temperature dependences of liquid alloy properties. The given phenomenon was observed only when the initial materials had a heterogeneous crystalline structure. This is associated with conservation of microscopic inhomogeneities (1-10 nm) in the melt, inherited from the initial materials or appearing when the components are mixed near the liquidus. Such aggregates represent a disperse phase enriched with one of the components being in metastable equilibrium with the dispersion phase of a different composition. The colloidal state is irreversibly destroyed with temperature increase to values T-hom characteristic of the given composition. Then the system transfers to the state of a true solution which is stable in the entire zone above liquidus. The introduction of surface-active elements that reduce the interface tension at the boundaries of colloidal particles leads to destruction of microheterogeneity at lower temperatures. After transition of the system to a true solution state, the ingot or metallic glass structure which forms on cooling or quenching changes greatly. In systems with immiscibility gaps, one can get a macrohomogeneous fine-disperse structure of the frozen emulsion. In the Cahn-Hilliard approximation, the authors analyse the model system including a disperse particle weighted in a dispersion phase of another composition, confirming the concept.
Author keywords:
ALLOYS
DOI:
нет данных
Web of Science ID:
ISI:A1995TP87400001
Соавторы в МНС:
Другие поля
Поле Значение
Month OCT
Publisher FREUND PUBLISHING HOUSE
Address STE 500, CHESHAM HOUSE, 150 REGENT ST, LONDON, ENGLAND W1R 5FA
Language English
Keywords-Plus ALLOYS
Research-Areas Materials Science
Web-of-Science-Categories Materials Science, Multidisciplinary
Number-of-Cited-References 38
Usage-Count-Last-180-days 1
Usage-Count-Since-2013 4
Journal-ISO High Temp. Mater. Process.
Doc-Delivery-Number TP874