EFFECT OF HYDROSTATIC-PRESSURE ON THE BAND-GAP LUMINESCENCE OF STRAIN-ADJUSTED SIMGEN SUPERLATTICES

We report an experimental study of the band-gap photoluminescence from strain-adjusted SimGen (m=9,6,3; n=6,4,2) superlattices under applied hydrostatic pressure. The strain adjustment was achieved by a thick, step-graded Si1-xGex buffer layer resulting in an improved quality of the superlattice with respect to dislocation density. The no-phonon (N P) lines shift linearly under applied hydrostatic pressure in all supe rlattices to lower energies. The stress dependence was modeled using a n approach based on deformation potentials and effective-mass theory. Under the assumptions made a close resemblance between experiment and theory was found. From the slopes of the stress shifts and amplitudes under various pressures, further evidence is given to an earlier assig nment of the NP lines as arising from band-to-band recombination.