The Diffusion of Lead and Bismuth into Single Crystals of Undoped and Bismuth-Doped Lead Sulfide at 700°C

Abstract

The simultaneous diffusion of ²¹⁰Pb and ²¹⁰Bi into undoped single crystals of lead sulfide and single crystals doped with 4×10¹⁸ and 4×10¹⁹ bismuth atoms/cm³ has been studied as a function of deviations from stoichiometry at 700°C. The diffusion coefficients for lead and for bismuth were identical. The identical values of the lead and bismuth diffusion coefficients suggest that Coulombic attraction between V_Pb′ and Bi_Pb is negligible. Although the addition of 4×10¹⁸ atoms of bismuth to lead sulfide does not change the diffusion coefficients of ²¹⁰Pb and of ²¹⁰Bi relative to undoped lead sulfide for −6.5ps₂) 19 atoms of bismuth does. This result and other evidence indicates a higher concentration of native lattice defects than previously considered. For logps₂>−3.9, the diffusion coefficients in undoped and lightly doped (4×10¹⁸ Bi) material are proportional to ¼ logps₂. Because the concentration of singly ionized cation vacancies is also proportional to ¼ logps₂, it is concluded that the singly ionized cation vacancy is the predominant defect through which ²¹⁰Pb and ²¹⁰Bi diffuse and may be the majority cation defect in lead sulfide at 700°C. For a logps₂<−3.9, the diffusion coefficients are independent of composition presumably because the as‐grown crystals contain microprecipitates of lead which dissolve extremely slowly under low sulfur pressures. Hence, these crystals contained essentially a constant concentration of defects.