Wettability and Interfacial Reactions Between Metallic Glass Melts and Cu/Mo Used as Roller Materials for Twin-Roll Casting

doi:10.1007/s40195-021-01356-5

Abstract

Abstract:

Twin-roll casting has been recently revealed to be an efficient technique to produce rejuvenated metallic glass (MG) strips. Due to the high melting point and high hardness, pure Mo is considered as a good roller material as pure Cu. However, the wettability and interfacial reactions between MG melts and Cu or Mo remain largely unknown. In this work, a series of sessile droplet wetting experiments are designed to investigate the wettability and reactions between Zr_41.2Ti_13.8Cu_12.5Ni₁₀Be_22.5 (Vit.1) or (Zr_0.401Ti_0.133Cu_0.118Ni_0.101Be_0.247)₉₉Nb₁ (Nb1) MG melts and Cu/Mo substrates at temperatures of 1073, 1123 and 1173 K. It is found that the wettability and interfacial reactions of the Vit.1 and Nb1 MG melts on the Cu substrates are very similar. The equilibrium contact angles are ~ 30° at 1073 K and ~ 25°-27° at 1123 K. The MG melts completely spread out on the Cu substrates at 1173 K. Cu substrates are slightly dissolved in the MG melts event at 1073 K, and a transitional reaction layer exists between the droplet and the Cu substrate. In comparison, the Vit.1 MG melt exhibits a much improved wettability on the Mo substrate. The equilibrium contact angle of the Vit.1/Mo is only 6° at 1073 K and 5° at 1123 K. No significant diffusion of Mo into the droplet occurs even at 1173 K with a holding time of ~ 30 min. The interfaces of the Vit.1/Mo samples are sharp, and no interfacial reaction layers form. These findings indicate that pure Mo can be a good roller material for twin-roll casting at high temperatures, and the Mo-made rollers are expected of capability to produce MG strips with good quality.

Key words: Metallic glass, Wettability, Interfacial reaction, Twin-roll casting, Roller material

Yi Wu, Long Zhang, Hongwei Zhang, Huameng Fu, Zhengwang Zhu, Hong Li, Aimin Wang, Haifeng Zhang. Wettability and Interfacial Reactions Between Metallic Glass Melts and Cu/Mo Used as Roller Materials for Twin-Roll Casting[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(7): 1221-1230.

Figures/Tables 9

Fig. 1 Top-view images of a-c Vit.1/Cu, d-f Nb1/Cu, g-i Vit.1/Mo wetting samples held at 1073, 1123 and 1173 K, respectively. The silver white spots are solidified MG droplets, which spreads on the substrates at high temperatures because of the good wettability

Fig. 2 In situ recorded images showing the equilibrium contact angles of a-c Vit.1/Cu samples at 1073, 1123 and 1173 K, respectively, d-f Nb1/Cu samples at 1073, 1123 and 1173 K, respectively, g-i Vit.1/Mo samples at 1073, 1123 and 1173 K, respectively

Fig. 3 Evolution of contact angles of the Vit.1/Cu, Nb1/Cu and Vit.1/Mo samples at three different holding temperatures versus the holding time

Fig. 4 SEM micrographs of the cross sections of the wetting samples: a Vit.1/Cu at 1073 K, b Vit.1/Cu at 1123 K, c Nb1/Cu at 1073 K, d Nb1/Cu at 1123 K, e Vit.1/Cu at 1173 K, f Nb1/Cu at 1173 K, g Vit.1/Mo at 1073 K, h Vit.1/Mo at 1123 K, i Vit.1/Mo at 1173 K, respectively

Fig. 5 Detailed micrographs of the interfacial regions of the wetting samples: a Vit.1/Cu at 1073 K, b Vit.1/Cu at 1123 K, c Vit.1/Cu at 1173 K, d Nb1/Cu at 1073 K, e Nb1/Cu at 1123 K, f Nb1/Cu at 1173 K, g Vit.1/Mo at 1073 K, h Vit.1/Mo at 1123 K, i Vit.1/Mo at 1173 K, respectively

Fig. 6 EDS elemental mappings of the interfacial regions in the Vit.1/Cu samples held at a 1073 K, b 1123 K, c 1173 K, respectively

Fig. 7 EDS elemental mappings of the interfacial regions in the Nb1/Cu samples held at a 1073 K, b 1123 K, c 1173 K, respectively

Fig. 8 EDS elemental mappings of the interfacial regions in the Vit.1/Mo samples held at a 1073 K, b 1123 K, c 1173 K, respectively

Fig. 9 Schematic illustration of the wettability and interfacial reactions of a Vit.1/Cu or Nb1/Cu at the beginning of holding, b Vit.1/Cu or Nb1/Cu at the final stage of holding and c Vit.1/Mo at the beginning of holding

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