Composition-Dependent Phonon and Thermodynamic Characteristics of C-Based XxY1−xC (X, Y ≡ Si, Ge, Sn) Alloys

Abstract: Novel zinc-blende (zb) group-IV binary XC and ternary XxY1−xC alloys (X, Y ≡ Si, Ge, and Sn) have recently gained scientific and technological interest as promising alternatives to silicon for high-temperature, high-power optoelectronics, gas sensing and photovoltaic applications. Despite numerous efforts made to simulate the structural, electronic, and dynamical properties of binary materials, no vibrational and/or thermodynamic studies exist for the ternary alloys. By adopting a realistic rigid-ion-model (RI… Show more

“…Ge . C) ∆ SLs, the perusal of Figure 3a,b reveals some interesting features: (a) in agreement with the existing results of phonon dispersions for binary zb SiC and GeC materials [146,154], our simulations of ω (q ⃗) in SiC/GeC SLs confirms the FAPs (see: Figure 3b) appearing between 0 to 350 cm −1 [the common overlapping acoustic phonon region of SiC-GeC] while the other acoustic modes fall in the frequency range of 350 to 630 cm −1 and behave as confined modes in the SiC layer, (b) the calculations of FAPs by M-LCM have corroborated the results derived earlier using Rytov s model (see: Table 2), (c) the FAPs are weakly affected by varying ∆, and (d) the COMs are significantly influenced by ∆ (≡ 3) causing downward (upward) shifts of higher (lower) frequency optical modes (cf. Section 3.1.5).…”

“…Recently, theoretical simulations of phonon dispersions ω (q ⃗) for the zb XC (X = Si, Ge, and Sn) materials have appeared in the literature [146,154]. A closer look confirms significant divergences in their optical and acoustical phonon branches.…”

“…Calculations of phonon dispersions ω (q ⃗) for the bulk zb XC, YC materials are available [146,154] along the high-symmetry directions in the BZ. With the appropriate bulk phonon frequencies, the necessary force constants of the M-LCM method are obtained to simulate ω (q ⃗) for ideal (XC)m/(YC)n SLs, considering m = n = 10.…”

“…In the lack of such data for novel C-based (XC)m/(YC)n SLs, it is necessary to simulate Raman intensity profiles. Although the lattice dynamical calculations are known for the bulk SiC, GeC, and SnC materials [146,154], there exist either limited [153] or no reports for comprehending the phonon dispersions ω (q ⃗) of their SLs. To understand the impact of interfacial layer thickness on ω (q ⃗) as well as on Raman spectra, we presented here our systematic results for both the ideal (XC)m/(YC)n and graded (XC) ∆ /(X .…”

“…Except for a preliminary report [153], no methodological studies are available on the phonon dispersions ω q ⃗ of novel strained layer XC /(YC) SLs, especially for comprehending the prospects of FAPs, COMs, and IPMs. Due to the large lattice mismatch between SiC-GeC (~5.0%), GeC-SnC (~10.5%), and SiC-SnC (~15.0%) [154], one would expect stress in the planes parallel and perpendicular to the SL interfaces. The optical and electrical processes in GaN-, AlN-, and InN-based MQWs and SLs are remarkably influenced by the existence of graded interfaces [155].…”

Strain-Dependent Effects on Confinement of Folded Acoustic and Optical Phonons in Short-Period (XC)m/(YC)n with X,Y (≡Si, Ge, Sn) Superlattices

“…Ge . C) ∆ SLs, the perusal of Figure 3a,b reveals some interesting features: (a) in agreement with the existing results of phonon dispersions for binary zb SiC and GeC materials [146,154], our simulations of ω (q ⃗) in SiC/GeC SLs confirms the FAPs (see: Figure 3b) appearing between 0 to 350 cm −1 [the common overlapping acoustic phonon region of SiC-GeC] while the other acoustic modes fall in the frequency range of 350 to 630 cm −1 and behave as confined modes in the SiC layer, (b) the calculations of FAPs by M-LCM have corroborated the results derived earlier using Rytov s model (see: Table 2), (c) the FAPs are weakly affected by varying ∆, and (d) the COMs are significantly influenced by ∆ (≡ 3) causing downward (upward) shifts of higher (lower) frequency optical modes (cf. Section 3.1.5).…”

“…Recently, theoretical simulations of phonon dispersions ω (q ⃗) for the zb XC (X = Si, Ge, and Sn) materials have appeared in the literature [146,154]. A closer look confirms significant divergences in their optical and acoustical phonon branches.…”

“…Calculations of phonon dispersions ω (q ⃗) for the bulk zb XC, YC materials are available [146,154] along the high-symmetry directions in the BZ. With the appropriate bulk phonon frequencies, the necessary force constants of the M-LCM method are obtained to simulate ω (q ⃗) for ideal (XC)m/(YC)n SLs, considering m = n = 10.…”

“…In the lack of such data for novel C-based (XC)m/(YC)n SLs, it is necessary to simulate Raman intensity profiles. Although the lattice dynamical calculations are known for the bulk SiC, GeC, and SnC materials [146,154], there exist either limited [153] or no reports for comprehending the phonon dispersions ω (q ⃗) of their SLs. To understand the impact of interfacial layer thickness on ω (q ⃗) as well as on Raman spectra, we presented here our systematic results for both the ideal (XC)m/(YC)n and graded (XC) ∆ /(X .…”

“…Except for a preliminary report [153], no methodological studies are available on the phonon dispersions ω q ⃗ of novel strained layer XC /(YC) SLs, especially for comprehending the prospects of FAPs, COMs, and IPMs. Due to the large lattice mismatch between SiC-GeC (~5.0%), GeC-SnC (~10.5%), and SiC-SnC (~15.0%) [154], one would expect stress in the planes parallel and perpendicular to the SL interfaces. The optical and electrical processes in GaN-, AlN-, and InN-based MQWs and SLs are remarkably influenced by the existence of graded interfaces [155].…”

Strain-Dependent Effects on Confinement of Folded Acoustic and Optical Phonons in Short-Period (XC)m/(YC)n with X,Y (≡Si, Ge, Sn) Superlattices