Electrical conductivity, thermoelectric power and Hall coefficient of β-FeSi2 doped with cobalt (n-type) or aluminium (p-type) are measured between 100 and 1200 °K. The conductivity of n-FeSi2 follows an exponential dependence on temperature. The temperature dependence of the thermoelectric power cannot be interpreted on the basis of conduction in a band. With the assumption that conduction in n-FeSi2 is caused by small polarons, the mobility at room temperature is found to be μn = 0.26 cm2/Vs. The activation energy of the mobility is 0.06 eV, the density of states N = 1.2 × 1022 cm−3. The electrical properties of p-FeSi2 can be interpreted using the band model with a hole mobility μp ≈ 2 cm2/Vs, which varies as T−1/2 in the region of extrinsic conduction. From intrinsic conduction a band gap of 0.9 to 1.0 eV is deduced. The disappearance of the thermoelectric power at high temperature is related to the semiconductor-to-metal transition at 1200 °K.
[1]
A. J. Bosman,et al.
Mechanism of the Electrical Conduction in Li-Doped NiO
,
1966
.
[2]
T. Holstein,et al.
Studies of polaron motion: Part III: The Hall mobility of the small polaron
,
1963
.
[3]
K. Schotte.
The thermoelectric properties of the small polaron
,
1966
.
[4]
J. Schnakenberg.
The Hall coefficient of the small polaron
,
1965
.
[5]
D. Adler,et al.
THEORY OF SEMICONDUCTOR-TO-METAL TRANSITIONS
,
1967
.
[6]
T. Holstein,et al.
Studies of polaron motion: Part II. The “small” polaron
,
1959
.
[7]
W. D. Johnston,et al.
Mechanism of Conduction in Li‐Substituted Transition Metal Oxides
,
1957
.
[8]
L. Friedman.
Density Matrix Formulation of Small-Polaron Motion
,
1964
.