E. J. W. Verwey scite author profile

LETTERS TO THE EDITOR dilution used, 0.0000577Nw, gave an equivalent conductivity of 372.4 mhos, compared with Mr. Dye's 360.5 for his most dilute solution, 0.001089N~. The graph also shows the Onsager slope, calculated from the latest value for myristyl ion, 371.6 (2). It will be seen that the conductivity in this dilute region rises above its infinite dilution value, "a phenomenon which seems to admit of no other interpretation than the formation of (probably small) micelles" (3). This conclusion was also reached in the paper to which this experimental work is an extension. It would probably be found true for all colloidal electrolytes if special care were given to the study of the most dilute solutions.

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Electronic conductivity and transition point of magnetite (“Fe3O4”)

Verwey

Haayman

1941

Physica

917

373

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Physical Properties and Cation Arrangement of Oxides with Spinel Structures II. Electronic Conductivity

Verwey¹,

Haayman²,

Romeijn³

1947

689

229

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The relations between the electronic conductivity of certain spinels and the arrangement of the cations in the crystal structure (see preceding paper) are studied. Several arguments favor the assumption that Fe3O4 contains both divalent and trivalent iron in the 16-fold position. The transition point in the neighborhood of liquid-air temperature is probably associated with an increased degree of order at low temperature in the distribution of the 8 electrons between the 16 Fe-lattice points per unit cell. The considerably increased conductivity below the transition points shows tetragonal anisotropy when the crystal is cooled in a magnetic field. The possible distributions of the electrons in the crystal at low temperature are discussed. In more complicated spinels, containing other metal atoms as well as iron in both the divalent and the trivalent state, the electronic interchange is more or less inhibited by the foreign metal atoms. The higher values of their resistance in comparison to that of Fe3O4 can be roughly described by an increased activation energy. The investigation of a number of substances with different arrangements of the cations shows that the activation energy (and therefore the electrical resistance) is lowest for those cases in which the electrons can travel, as in Fe3O4, along the Fe of the 16-fold position.

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E. J. W. Verwey

Theory of the stability of lyophobic colloids

Electronic Conduction of Magnetite (Fe3O4) and its Transition Point at Low Temperatures

Theory of the Stability of Lyophobic Colloids.

Electronic conductivity and transition point of magnetite (“Fe3O4”)

Physical Properties and Cation Arrangement of Oxides with Spinel Structures II. Electronic Conductivity

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