Quasichemical equations for oxygen and sulphur in liquid binary alloys


Autoria(s): Jacob, KT; Alcock, CB
Data(s)

01/02/1972

Resumo

An equation has been derived for predicting the activity coefficient of oxygen or sulphur in dilute solution in binary alloys, based on the quasichemical approach, where the metal atoms and the oxygen atoms are assigned different bond numbers. This equation is an advance on Alcock and Richardson's earlier treatment where all the three types of atoms were assigned the same coordination number. However, the activity coefficients predicted by this new equation appear to be very similar to those obtained through Alcock and Richardson's equation for a number of alloy systems, when the coordination number of oxygen in the new model is the same as the average coordination number used in the earlier equation. A second equation based on the formation of “molecular species” of the type XnO and YnO in solution is also derived, where X and Y atoms attached to oxygen are assumed not to make any other bonds. This equation does not fit experimental data in all the systems considered for a fixed value of n. Howover, if the strong oxygen-metal bonds are assumed to distort the electronic configuation around the metal atoms bonded to oxygen and thus reduce the strength of the bonds formed by these atoms with neighbouring metal atoms by approximately a factor of two, the resulting equation is found to predict the activity coefficients of oxygen that are in good agreement with experimental data in a number of binary alloys.

Formato

application/pdf

Identificador

http://eprints.iisc.ernet.in/42455/1/007._Quasichem_Eqs._Acta_Met._1972.pdf

Jacob, KT and Alcock, CB (1972) Quasichemical equations for oxygen and sulphur in liquid binary alloys. In: Acta Metallurgica, 20 (2). pp. 221-232.

Publicador

Elsevier Science

Relação

http://dx.doi.org/10.1016/0001-6160(72)90184-8

http://eprints.iisc.ernet.in/42455/

Palavras-Chave #Materials Engineering (formerly Metallurgy)
Tipo

Journal Article

PeerReviewed