Glass transformation, heat capacity and structure of ASxSe1−xglasses studied by modulated temperature differential scanning calorimetry experiments

Abstract

The recent novel temperature modulated differential scanning calorimetry (MDSC^TM TA Instruments Inc. USA) technique has been applied to the measurement of the thermal properties of chalcogenide glasses of the As-Se system in the glass transition region. All samples in this work were given the same thermal history by heating to a temperature above the glass transition, equilibrating and then cooling at a rate of 5°Cmin¹ to a temperature of 20°C. The reversing and non-reversing heat flows through the glass transformation region during both heating and cooling schedules were measured and the values of the parameters T_g , ΔH, C_p and ΔC_p , which characterize the thermal events in the glass transition region, were determined. The ability to determine the reversible heat flow in MDSC enables an accurate measurement to be made of the true heat capacity (that normally associated with reversible heat flow). This could not be done hitherto in conventional thermal analysis where the detected heat flow is the total heat flow, i.e. the sum of reversing and non-reversing heat flows. The structurally determined parameters T _g, ΔH, C_p and ΔC_p , reveal extrema when the As-Se glass system reaches the average coordination number (r) = 2·40 at 40at.% As, which correspond to the stoichiometric composition As₂Se₃. We also observed local extrema in the composition dependence of the above thermal parameters at 16·6 and 28·5 at.% As, which correspond to the stoichiometric compositions As₂Se₁₀ and As₂Se₅ with average coordination numbers 2·52 and 2·57, respectively. No such clear local extrema below the 40at.% As composition could be observed previously in thermal analysis. We compare our MDSC results with previously published works on glass transition in As-Se glasses and discuss the results in terms of recent structural models for chalcogenide glasses.