TY - JOUR
T1 - Probing Lattice Dynamics and Electronic Resonances in Hexagonal Ge and SixGe1- xAlloys in Nanowires by Raman Spectroscopy
AU - De Matteis, Diego
AU - de Luca, Marta
AU - Fadaly, Elham M.T.
AU - Verheijen, Marcel A.
AU - López-Suárez, Miquel
AU - Rurali, Riccardo
AU - Bakkers, Erik P.A.M.
AU - Zardo, Ilaria
PY - 2020/6/23
Y1 - 2020/6/23
N2 - Recent advances in nanowire synthesis have enabled the realization of crystal phases that in bulk are attainable only under extreme conditions, i.e., high temperature and/or high pressure. For group IV semiconductors this means access to hexagonal-phase SixGe1-x nanostructures (with a 2H type of symmetry), which are predicted to have a direct band gap for x up to 0.5-0.6 and would allow the realization of easily processable optoelectronic devices. Exploiting the quasi-perfect lattice matching between GaAs and Ge, we synthesized hexagonal-phase GaAs-Ge and GaAs-SixGe1-x core-shell nanowires with x up to 0.59. By combining position-, polarization-, and excitation wavelength-dependent μ-Raman spectroscopy studies with first-principles calculations, we explore the full lattice dynamics of these materials. In particular, by obtaining frequency-composition calibration curves for the phonon modes, investigating the dependence of the phononic modes on the position along the nanowire, and exploiting resonant Raman conditions to unveil the coupling between lattice vibrations and electronic transitions, we lay the grounds for a deep understanding of the phononic properties of 2H-SixGe1-x nanostructured alloys and of their relationship with crystal quality, chemical composition, and electronic band structure.
AB - Recent advances in nanowire synthesis have enabled the realization of crystal phases that in bulk are attainable only under extreme conditions, i.e., high temperature and/or high pressure. For group IV semiconductors this means access to hexagonal-phase SixGe1-x nanostructures (with a 2H type of symmetry), which are predicted to have a direct band gap for x up to 0.5-0.6 and would allow the realization of easily processable optoelectronic devices. Exploiting the quasi-perfect lattice matching between GaAs and Ge, we synthesized hexagonal-phase GaAs-Ge and GaAs-SixGe1-x core-shell nanowires with x up to 0.59. By combining position-, polarization-, and excitation wavelength-dependent μ-Raman spectroscopy studies with first-principles calculations, we explore the full lattice dynamics of these materials. In particular, by obtaining frequency-composition calibration curves for the phonon modes, investigating the dependence of the phononic modes on the position along the nanowire, and exploiting resonant Raman conditions to unveil the coupling between lattice vibrations and electronic transitions, we lay the grounds for a deep understanding of the phononic properties of 2H-SixGe1-x nanostructured alloys and of their relationship with crystal quality, chemical composition, and electronic band structure.
KW - crystal structure transfer
KW - hexagonal (lonsdaleite) SiGe
KW - nanowires
KW - phonons
KW - Raman spectroscopy
KW - resonant Raman
UR - http://www.scopus.com/inward/record.url?scp=85087094803&partnerID=8YFLogxK
U2 - 10.1021/acsnano.0c00762
DO - 10.1021/acsnano.0c00762
M3 - Article
C2 - 32392038
AN - SCOPUS:85087094803
SN - 1936-0851
VL - 14
SP - 6845
EP - 6856
JO - ACS Nano
JF - ACS Nano
IS - 6
ER -