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Absolute thermoelectric power of Cr-Mo alloys between 100 and 600°K

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Physik der kondensierten Materie

Abstract

Thermoelectric power measurements on Cr-Mo alloys showed that the Seebeck coefficientS of alloys with more than 25 at % Mo was a linear function of temperature between 100 and 500°K.S showed a more complex temperature dependence for antiferromagnetic samples, withS(T) having a peak below the Neel temperature. The onset of antiferromagnetism was close to the minimum in theS(T) curve. The energy change associated with antiferromagnetic ordering is of the same order of magnitude as the energy gap predicted by the spin density wave theory.

Résumé

Les mesures de force thermoélectrique effectuées sur des alliages Cr-Mo montrent que le coefficient de SeebeckS est une fonction linéaire de la température entre 100 et 500°K pour tous les échantillons contenant plus de 25% at. Mo.

Par contre, le comportement deS(T) est plus complexe dans le cas d'échantillons antiferromagnétiques. On observe d'une part un pic au dessous de la température de Néel. D'autre part le point de transition antiferromagnétique correspond assez bien à l'endroit du minimum deS(T). La différence d'énergie associée à cette transition antiferromagnétique est du même ordre de grandeur que le “gap” calculé à l'aide de la théorie des ondes de spin.

Zusammenfassung

Messungen der Thermokraft von Cr-Mo-Verbindungen zeigten, daß der Seebeck-KoeffizientS von Verbindungen mit mehr als 25 Atomprozent Mo zwischen 100 und 500°K proportional der Temperatur ist. Für antiferromagnetische Proben zeigteS ein kompliziertes Verhalten, nämlich ein relatives Maximum unterhalb der Néel-Temperatur. Der Einsatz des Antiferromagnetismus lag nahe beim Minimum derS(T)-Kurve. Die mit der antiferromagnetischen Ordnung verbundene Energieänderung ist von der gleichen Größenordnung wie die von der Spinwellentheorie vorausgesagte Energielücke.

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Author notes

  1. Harry Tomaschke

    Present address: Greenville College, Greenville, Illinois

Authors and Affiliations

  1. Department of Chemical Engineering and Metallurgy, Syracuse University, Building D-6, Collendale Campus, 13210, Syracuse, N.Y., USA

    Klaus Schröder & Harry Tomaschke

Authors
  1. Klaus Schröder
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  2. Harry Tomaschke
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Schröder, K., Tomaschke, H. Absolute thermoelectric power of Cr-Mo alloys between 100 and 600°K. Phys kondens Materie 7, 318–324 (1968). https://doi.org/10.1007/BF02422810

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  • DOI: https://doi.org/10.1007/BF02422810

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