The article raises the question of how diffusion pairs A/B,A/C,and B/C form in three-component alloys ABC.This issue solves experimentally using the TEM(transmission electron microscopy)method and Ni65Mo20Cr15 alloy.T...The article raises the question of how diffusion pairs A/B,A/C,and B/C form in three-component alloys ABC.This issue solves experimentally using the TEM(transmission electron microscopy)method and Ni65Mo20Cr15 alloy.The quenching of this alloy from a liquid showed that such pairs form in the liquid state of the alloy,and as the quenching temperature decreases,particles of the new phases form inside them.We concluded that not a disordered solid solution after high-temperature quenching“from a region of disordered solid solution at the phase diagrams”is the starting point for the formation of a low-temperature microstructure,but a liquid state,into which the alloy passes during its melting.The author hopes the results got will lead to a reorientation of our ideas about alloys and will change a lot both in the theory of alloys and in the technology of their manufacture.展开更多
The article presents a generalization of our electron microscopic results got on some binary and ternary alloys based on Ni,Fe or Co.They are considered as the basis for the conclusion that chemical bonds between atom...The article presents a generalization of our electron microscopic results got on some binary and ternary alloys based on Ni,Fe or Co.They are considered as the basis for the conclusion that chemical bonds between atoms are realized in alloys according to the principle of pair interaction.This process begins with the separation of the alloy into diffusion micro-pairs already in the liquid state,which makes it possible to consider the liquid state of the alloy as the initial stage of the new phase formation.With a subsequent decrease in temperature,particles of a new phase form inside a diffusion micro-pair.The formation of diffusion micro-pairs and phases within them occurs due to the existence in alloys,along with a metallic bond,of ionic and covalent components of a strong chemical bond at all temperatures of the condensed state.The article shows what exactly needs to be done so that such a branch of science as materials science could get rid of the empirical approach when creating new alloys.展开更多
The paper discusses the researches that formed the basis of the study of the transition of “ordering-phase separation” and the reasons for such transition occurrence. Experimental results have presented what diffusi...The paper discusses the researches that formed the basis of the study of the transition of “ordering-phase separation” and the reasons for such transition occurrence. Experimental results have presented what diffusion pairs are and how they occur in binary and multicomponent alloys. The paper illustrates that the chemical bonds between atoms are realized on the principle of pair interaction in both solid and liquid states of the alloy. The process of separating a multi-component ABC alloy into diffusion pairs A/B, A/C, and B/C occurs in a liquid solution, where the diffusion mobility of atoms is very high, and the resistance of the environment is relatively low. The driving force of such a process is the chemical attraction between like and unlike atoms, that is, the tendency to phase separation and the tendency to ordering. Quenching the liquid alloy into the water fixes a microstructure consisting of microscopic areas corresponding in composition to one or another diffusion pairs. The paper shows what exactly should be done so that such a branch of science as Materials Science could get rid of the empirical approach when creating new alloys.展开更多
文摘The article raises the question of how diffusion pairs A/B,A/C,and B/C form in three-component alloys ABC.This issue solves experimentally using the TEM(transmission electron microscopy)method and Ni65Mo20Cr15 alloy.The quenching of this alloy from a liquid showed that such pairs form in the liquid state of the alloy,and as the quenching temperature decreases,particles of the new phases form inside them.We concluded that not a disordered solid solution after high-temperature quenching“from a region of disordered solid solution at the phase diagrams”is the starting point for the formation of a low-temperature microstructure,but a liquid state,into which the alloy passes during its melting.The author hopes the results got will lead to a reorientation of our ideas about alloys and will change a lot both in the theory of alloys and in the technology of their manufacture.
文摘The article presents a generalization of our electron microscopic results got on some binary and ternary alloys based on Ni,Fe or Co.They are considered as the basis for the conclusion that chemical bonds between atoms are realized in alloys according to the principle of pair interaction.This process begins with the separation of the alloy into diffusion micro-pairs already in the liquid state,which makes it possible to consider the liquid state of the alloy as the initial stage of the new phase formation.With a subsequent decrease in temperature,particles of a new phase form inside a diffusion micro-pair.The formation of diffusion micro-pairs and phases within them occurs due to the existence in alloys,along with a metallic bond,of ionic and covalent components of a strong chemical bond at all temperatures of the condensed state.The article shows what exactly needs to be done so that such a branch of science as materials science could get rid of the empirical approach when creating new alloys.
文摘The paper discusses the researches that formed the basis of the study of the transition of “ordering-phase separation” and the reasons for such transition occurrence. Experimental results have presented what diffusion pairs are and how they occur in binary and multicomponent alloys. The paper illustrates that the chemical bonds between atoms are realized on the principle of pair interaction in both solid and liquid states of the alloy. The process of separating a multi-component ABC alloy into diffusion pairs A/B, A/C, and B/C occurs in a liquid solution, where the diffusion mobility of atoms is very high, and the resistance of the environment is relatively low. The driving force of such a process is the chemical attraction between like and unlike atoms, that is, the tendency to phase separation and the tendency to ordering. Quenching the liquid alloy into the water fixes a microstructure consisting of microscopic areas corresponding in composition to one or another diffusion pairs. The paper shows what exactly should be done so that such a branch of science as Materials Science could get rid of the empirical approach when creating new alloys.
