Raman investigation of GaP–Si interfaces grown by molecular beam epitaxy

Raman spectroscopy was used to investigate the residual strain in thin GaP layers deposited on Si substrates by molecular beam epitaxy. Different growth conditions were used to obtain a clean GaP–Si interface, including migration enhanced epitaxy. The strain induced Raman shifts of the longitudinal and the transverse optical GaP lattice modes were analyzed. The effects of crystalline defects are discussed, supported by high resolution transmission electron microscopy and X-ray scattering studies. Finally, Raman Spectroscopy reveals the presence of disorder (or surface)-activated optical phonons. This result is discussed in the light of surface morphology analyses.

► GaP thin layers grown by molecular beam epitaxy on Si substrates.
► Strain-induced Raman shifts of the optical GaP modes are analyzed.
► Simulation of optical GaP modes by density functional perturbation theory.
► Comparison with X-ray diffraction and electron and scanning probe microscopy data.