Crystallization Kinetics of ZrxTiNiCuBe High-Entropy Bulk Metallic Glasses

Non-equiatomic ZrxTiNiCuBe (x-1.5, 2, 2.5, 3, 3.5, at%) high-entropy bulk metallic glasses (HE-BMGs) were prepared by copper mold casting method, and the crystallization kinetics was studied by differential scanning calorimeter (DSC) under both non-isochronal and isothermal conditions. The non-isothermal crystallization kinetics of ZrxTiNiCuBeHE-BMGs show a multiple-stage process. The characteristic temperatures increase with the increase in the heating rate, showing obvious kinetics effects. The activation energy calculated by the Kissinger equation shows. an order of E-g>E-x>E-pl, indicating that overcoming the energy barrier for the rearrangement is more difficult than atoms nucleation process and the grain growth process of crystallization. The activation energy of crystallization event is in the order of ExEyEs, demonstrating the non-isothermal crystallization processing is from easy to difficult. The activation energy increases and then decreases with the increase in Zr content. Zr2TiNiCuBe HE-BMG has a larger activation energy and better thermal stability than others. Isothermal crystallization shows a single exothermic behavior after different incubation periods. As isothermal temperature increases, incubation time decreases rapidly and the width of exothermic peak decreases markedly. The crystallization volume fraction (x) vs time (1) curves are typical "S" type. With the decrease in isothermal temperature, the x vs 1 curves become gentle, indicating that the process of crystallization slows down. The local crystallization activation energy for isothermal processing was calculated using the Arrhenius formula. With the increase in Zr content, the local crystallization activation energy gradually decreases and the thermal stability decreases. The Avrami exponent obtained by the Johnson-Mehl-Avrami (JMA) equation is between 1.5 and 2.5, indicating that the isothermal crystallization mechanism is mainly a diffusion-controlled growth process with a nucleation rate decrease.