Key points are not available for this paper at this time.
The conductivity of an n-type semiconductor has been calculated in the region of low-temperature T and low impurity concentration n₃. The model is that of phonon-induced electron hopping from donor site to donor site where a fraction K of the sites is vacant due to compensation. To first order in the electric field, the solution to the steady-state and current equations is shown to be equivalent to the solution of a linear resistance network. The network resistance is evaluated and the result shows that the T dependence of the resistivity is ({₃}kT). For small K, ₃= (e^{2}{₀}) (4{{n₃}3) }^1{3} (1-1. 35K^1{3}), where ₀ is the dielectric constant. At higher K, ₃ and attain a minimum near K=0. 5. The dependence on n₃ is extracted; the agreement of the latter and of ₃ with experiment is satisfactory. The magnitude of is in fair agreement with experiment. The influence of excited donor states on is discussed.
Miller et al. (Tue,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: