Evidence of a Glass–Liquid Transition in a Gold–Germanium–Silicon Alloy

Abstract

Gold‐rich (73–81 at.% Au) alloys of gold–germanium–silicon were “splat” cooled to an amorphous solid form. Thermal and rheological evidence of a glass‐liquid transition in the Au_0.77Ge_0.136Si_0.094 alloy is reported. The transition was manifested thermally by an abrupt rise of 5.5 cal/g‐atom·°K in specific heat, $C_p$ , as the alloy was heated from 285° to 297°K. Just above 297°K, $C_p$ starts to fall with increasing T on a reasonable extrapolation of the high‐temperature $C_p\mathrm{–T}$ relation of the liquid alloy. This thermal behavior could be repeated on the same sample after it had been carried through the transition and chilled again. The apparent glass‐transition temperature was increased by 1°–3° by increasing the heating rate by a factor of 16. The viscosity $\eta$ of the amorphous alloy increases rapidly with falling temperature from 0.9 × 10⁹ P at 305°K to 1.4 × 10¹³ P at 285°K and is described by the equation: $\text{η\hspace{0.17em}=\hspace{0.17em}0.52}\exp \text{[136\hspace{0.17em}/\hspace{0.17em}(T\hspace{0.17em}−\hspace{0.17em}241.3)]}\mathrm{P}$ . The steady isothermal viscosity is independent of stress over the range 3–140 kg/cm². Our finding that abrupt temperature changes in the high‐viscosity regime shifts $\eta$ rather little initially indicates that $\eta$ depends primarily on configuration rather than temperature per se. We have also measured the enthalpy and resistivity of the alloy in its various states.