1. Vibrational spectroscopy of periodical semiconductor nanostructures with quantum dots. Introduction The problem Results Conclusion Mikhail Ladanov

2. Dielectric function: Bruggeman effective dielectric function approximation: IR spectra Effective dielectric function Dielectric function of matrix Dielectric function of QD * s h

3. IR spectra of AlAs stuctures with QDs  Features corresponded to TO phonons in AlAs QD.  Low freq. shift of TO phonon in respect to the bulk one due to the stress..  There’s no LO phonon peak.

4. Basic equations Dielectric continuum approximation: Lap. Eq. solution: (for prolate QD) Expression for freq. of IF phonons

5. IF phonons in QD. Oblate ellipsoid. R p /R e = 1/2

6. IF phonons in QD. Prolate ellipsoid. R p /R e = 2

7. Freq. of IF phonons in dep. of Re/Rp. Re/Rp

8. Experimental Raman spectra of InAs QDs/AlAs (a), AlAs QDs/InAs (b) and InAs QDs/GaAs (c) structures. There’re features between LO and TO phonons freq. which cannot be explained in the frames of 2D structure model for big difference of layers thickness.

9. Experimental Raman spectra of InAs/Al x Ga 1-x As structures for different x. Spectra, marked with the dotted line, are measured in z(xx)-z scattering geometry, while those, marked with the solid line – in z(xy)-z scattering geometry.

10. Freq. of IF phonons in InAs/AlGaAs structures - theory - experiment

11. Conclusion The IR reflection and Raman scattering of light by InAs/Al(Ga)As and AlAs/InAs periodic structures with self-organized quantum dots has been investigated. The Raman spectra measured in different scattering geometries exhibit features that correspond to optical TO and LO phonons and interface phonons. The frequencies of TO and LO phonons are displaced with respect to the corresponding values in bulk materials in view of mechanical stresses. The lines of Raman scattering by interface phonons are observed under conditions close to the resonance conditions. The frequencies of interface phonons lie in the spectral range between the frequencies of TO and LO phonons. The experimental frequencies of optical phonons have been used for calculating the frequencies of interface phonons in structures with quantum dots of different shapes in the approximation of a dielectric continuum. The frequencies of interface phonons obtained within this model depend on the shape of the quantum dots. It has been shown that the dielectric-continuum approximation is an adequate model for calculating the frequencies of interface phonons in InAs/Al x Ga 1–x As quantum-dot structures with any value of x. In this case, it is assumed that the shape of quantum dots is close to that observed in the spectra obtained by high-resolution electron microscopy. Thus, it has been shown that the Raman spectroscopy is sensitive to the shape of quantum dots.