Mechanical Properties, Elastic Constants, Lattice Vibrations

Basic Parameters
Elastic Constants
Acoustic Wave Speeds
Phonon Frequencies

Basic Parameters

Si_1-xGe_x		Remarks	Referens
Density	(2.329+3.493x-0.499x²)g cm^-3	300 K	Schaffler F. et al.(2001)

Surface microhardness	(1150 - 350x) kg mm^-2	300 K, using Knoop's pyramid test	Schaffler F. et al.(2001)
Lattice constant a(x)	( 5.431 + 0.20x + 0.027x²⁾ A	300 K	Dismukes et al. (1964b)

Elastic constants at 300 K.

Si_1-xGe_x. Elastic constants at 300 K.		Remarks	Referens
C₁₁	(165.8 - 37.3x ) GPa	300 K	Schaffler F. et al.(2001)
C₁₂	(63.9 - 15.6 x ) GPa	300 K
C₄₄	(79.6 - 12.8 x ) GPa	300 K

Si_1-xGe_x.	Bulk modulus (compressibility^-1)	For T = 300 K
	B_s=(C₁₁+2C₁₂)/3	B_s = (97.9 - 22.8x)^GPa	Schaffler F. et al.(2001)
	Anisotropy factor
	C'=(C₁₁-C₁₂)/2C₄₄	A = (0.64 - 0.04x)
	Shear modulus
	C'=(C₁₁-C₁₂)/2	C' = (51.0 - 10.85x) GPa
	[100] Young's modulus
	Y₀=(C₁₁+2C₁₂)·(C₁₁-C₁₂)/(C₁₁+C₁₂)	Y₀ = (130.2 - 28.1x) GPa	Wortman & Evans (1965)

Y₀=(C₁₁+2C₁₂)·(C₁₁-C₁₂)/(C₁₁+C₁₂)

Y₀ = 748 GPa (Gmelins Handbuch (1959))
Y₀ = 392-694 GPa (Harris et al.(1995c)

[100] Poisson ratio σ_o=C₁₂/(C₁₁+C₁₂) σ_o = (0.278- 0.005x) Wortman & Evans (1965)

	Si, Ge. Young's modulus vs. direction in the (001) plane. Wortman & Evans (1965)
	Si, Ge. Poisson ratio vs. direction in the (001) plane. Wortman & Evans (1965)

Acoustic Wave Speeds

SiGe. No data
see also Si.Acoustic Wave Speeds and Ge.Acoustic Wave Speeds

Phonon frequencies

phonon wavenumbers:			Remarks	Referens
Si	ν_LTO(Γ_25')	15.5 10¹² Hz	T=300K	see also Si. Phonon frequencies
	ν_TA(X₃)	4.5 10¹² Hz
	ν_LAO(X₁)	12.3 10¹² Hz
	ν_TO(X₄ )	13.9 10¹² Hz
	ν_TA (L₃)	3.45 10¹² Hz
	ν_LA(L_2')	11.3 10¹² Hz
	ν_LO(L₁)	12.6 10¹² Hz
	ν_TO(L_3')	14.7 10¹² Hz

Ge	ν_LTO(Γ_25')	9.02 10¹² Hz	T=300K	Nillsson & Nelin (1972)
	ν_TA(X₃)	2.385 10¹² Hz		see also Ge. Phonon frequencies
	ν_LAO(X₁)	7.14 10¹² Hz
	ν_TO(X₄ )	8.17 10¹² Hz
	ν_TA (L₃)	1.87 10¹² Hz
	ν_LA(L_2')	6.63 10¹² Hz
	ν_LO(L₁)	7.27 10¹² Hz
	ν_TO(L_3')	8.55 10¹² Hz

	Si. Dispersion curves for acoustic and optical phonons. Dolling (1963) and Tubino et al. (1972)
	Ge. Dispersion curves for acoustic and optical phonons. Weber (1977)

For a wide composition range three optical phonon modes dominate the Raman spectra of Si_1-xGe_x alloys. They are attributed to local vibrations of Si-Si, Si-Ge, and Ge-Ge atom pairs. Their relative intensities are roughly proportional to the abundance of the respective pairs-that is, (1 - x)², 2x(l - x), and x², respectively.

Si_1-xGe_x. Optical phonon Raman signals associated with local Si-Si, Si-Ge and Ge-Ge modes vs. composition
Alonso & Winer (1989)

New Semiconductor Materials. Biology systems. Characteristics and Properties

Mechanical Properties, Elastic Constants, Lattice Vibrations

Basic Parameters

Elastic constants at 300 K.

Acoustic Wave Speeds

Phonon frequencies

New Semiconductor Materials. Biology systems.
Characteristics and Properties