Design optimization of tensile-strained SiGeSn/GeSn quantum wells at room temperature

Abstract: A direct bandgap can be engineered in Ge-rich group-IV alloys by increasing Sn content and by introducing tensile strain in GeSn. Here, we combine these two routes in quantum well (QW) structures and systematically analyze the properties of SiGeSn/GeSn quantum wells for a range of Sn content, strain, and well width values, within realistic boundaries. Using the k Á p method, and including L-valley within the effective mass method, we find that 13-16 nm is a preferred range of well widths to achieve high gain f… Show more

“…[1][2][3][4][5][6][7][8][9][10][11][12] Composition of Sn for this transition is stated over a range, since the bowing parameter of Ge 1Ày Sn y in the computation of energy bandgap varies between experimental and first-principles calculations. 21 Additionally, Ge 1Ày Sn y material has inherent advantages, such as: (i) increased direct band transitions of the carriers between conduction and valence bands, improving optical absorption to provide high photodetector responsivities; [22][23][24] (ii) lower effective mass (m eff ) of carriers in the G-valley than L-valley enhances mobility -thereby boosting the ON-current in a low power transistor; 25,26 (iii) compatibility with Si CMOS technology; [27][28][29][30] (iv) high carrier lifetime due to reduced surface roughness 31 by mitigating surface states induced recombination. Hence, a virtually defect-free lattice matched GeSn/InAlAs (or InGaAs) heterostructure is necessary to make better use of Ge 1Ày Sn y material in photonic integrated circuits (PICs) and optoelectronic applications.…”

Lattice matched GeSn/InAlAs heterostructure: role of Sn in energy band alignment, atomic layer diffusion and photoluminescence

“…[1][2][3][4][5][6][7][8][9][10][11][12] Composition of Sn for this transition is stated over a range, since the bowing parameter of Ge 1Ày Sn y in the computation of energy bandgap varies between experimental and first-principles calculations. 21 Additionally, Ge 1Ày Sn y material has inherent advantages, such as: (i) increased direct band transitions of the carriers between conduction and valence bands, improving optical absorption to provide high photodetector responsivities; [22][23][24] (ii) lower effective mass (m eff ) of carriers in the G-valley than L-valley enhances mobility -thereby boosting the ON-current in a low power transistor; 25,26 (iii) compatibility with Si CMOS technology; [27][28][29][30] (iv) high carrier lifetime due to reduced surface roughness 31 by mitigating surface states induced recombination. Hence, a virtually defect-free lattice matched GeSn/InAlAs (or InGaAs) heterostructure is necessary to make better use of Ge 1Ày Sn y material in photonic integrated circuits (PICs) and optoelectronic applications.…”

Lattice matched GeSn/InAlAs heterostructure: role of Sn in energy band alignment, atomic layer diffusion and photoluminescence

Investigation of α-Sn Dependence of Band Structure and Optical Emission in Si/SiyGe1-x-ySnx/Si Quantum Well Laser

Depth-dependent photoluminescence characteristic of GeSn/SiGeSn multi-quantum wells