Elastic constants in monocrystalline tungsten under quasi-hydrostatic pressures to 11.3 GPa

Compressional (P) and shear (S) wave velocities of tungsten single crystals along the [100] and [110] directions were measured using ultrasonic interferometry at room temperature up to 11.3 GPa. Least-squares fitting of V P [ 100 ] , V S [ 100 ] , V P [ 110 ] , and pressure to finite strain (FS) equations yields the elastic constants: C₁₁ = 523.5(5) GPa, C₁₂ = 205.1(32) GPa, and C₄₄ = 160.8(4) GPa, along with their respective pressure derivatives: C 11 ′ = 6.20 ( 2 ) , C 12 ′ = 3.35 ( 1 ) , and C 44 ′ = 1.65 ( 6 ) . Using the Voigt-Reuss-Hill approximation, the elastic moduli were derived as K S 0 = 311.2 ( 22 ) GPa and G 0 = 160.2 ( 7 ) GPa , along with their respective pressure derivatives: K S 0 ′ = 4.30 ( 4 ) and G 0 ′ = 1.56 ( 1 ) . The Debye temperature of tungsten was determined to be 380.7(8) K, showing good agreement with previous calorimetric measurements. The elastic anisotropy increases slightly from 1.01(1) at ambient pressure to 1.03(1) at 11.3 GPa, suggesting that tungsten remains nearly isotropic under compression. Poisson's ratio slightly increased from 0.281(3) to 0.288(3) with pressure. Additionally, Pugh's ratio decreased from 0.512(4) to 0.494(4), while Pettifor's ratio increased from 0.148(10) to 0.175(10) as pressure reached 11.3 GPa. These results suggest that tungsten is weakly ductile compared to the critical thresholds for ductile behavior (i.e., Pugh's ratio <0.6 and Pettifor's ratio >0, indicating ductile behavior), but that its ductility increases marginally under pressure.