Phase Composition and Temperature Effect on the Dynamic Young's Modulus, Shear Modulus, Internal Friction, and Dilatometric Changes in AISI 4130 Steel

Elastic properties of materials and their changes with temperature are important for their applications in engineering. In the present study the influence of phase composition and temperature of AISI 4130 alloy on Young's modulus (E-d), shear modulus (G(d)), and damping (Q(-1)) was carried out by the impulse excitation technique (IET). The material characterization was performed using confocal microscopy, XRD, SEM, HV, and dilatometry. A stable structure, composed of ferrite (BCC) and pearlite (& alpha;-Fe + Fe3C), was obtained by annealing. Metastable structure of martensite (BCT) was obtained by quenching. The E-d, G(d), and Q(-1) were measured by varying the temperature from RT to 900 & DEG;C. The values of E-d and G(d), at RT, were determined as 201.5 and 79.2 GPa (annealed) and 190.13 and 76.5 GPa (quenched), respectively. In the annealed steel, the values E-d and G(d) decrease linearly on heating up to 650 & DEG;C, with thermal expansion. In the quenched steel, weak changes occurred in the dilatometric curve, E-d, G(d), and Q(-1), in the range of 350-450 & DEG;C, which indicated decompositions of the martensitic phase. A sharp decrease in the moduli and high peak of Q(-1) were observed for both samples around 650-900 & DEG;C, revealing low lattice elastic stability of the phases during transformations & alpha;(BCC) + Fe3C & gamma;(FCC).