A calorimetric study of thermodynamic properties for binary Cu–Ge alloys

“…The latent heat were estimated as 232.8, 198.2, and 163.5 kJ/kg for CuGe40, CuGe50, and CuGe60, respectively. The value of latent heat for CuGe40 is comparable to reference data (169.7 kJ/kg) (Zhai et al, 2012). Additionally, the heat storage density of CuGe50 increased in the temperature range 644-705°C owing to the latent heat from the primary Ge and sensible heat from the eutectic mixture, while the heat storage density of CuGe60 is enhanced in the temperature range 644-765°C.…”

“…There is a paucity of studies on the values of the specific heat (C p ) based on the temperature and thermophysical properties of the Cu-Ge alloy. The phase transition temperatures and enthalpy of fusion for Cu-Ge alloys with a wide range of chemical compositions have been examined (Zhai et al, 2012). In this study, the melting, solidification, and eutectic temperatures, enthalpies, and specific heat capacity of the alloys were measured using differential scanning calorimetry [DSC, NETZSCH DSC 404 F3 Pegasus ® manufactured by NETZSCH Co. Ltd., temperature resolution of ±0.0025 × |t|°C)] under an Ar flow of 100 ml/min with a heating and cooling rate of 10°C/min between room temperature and 900°C.…”

“…The latent heat were estimated as 41.8, 27.3, and 23.2 kJ/kg for CuGe40, CuGe50, and CuGe60, respectively. The value of latent heat for CuGe40 was estimated by reference data (28.4 kJ/kg) (Zhai et al, 2012). Strong discontinuous changes are the sum of sensible heat and latent heat released/stored in the solid/liquid phase transition (eutectic mixture of ε 2 + (Ge) 5 liquid phase) at a temperature of 644°C.…”

“…Si and Ge elements belong to the carbon group in the periodic table, in which the Cu-Ge alloy has a eutectic mixture containing Ge contents that may lead to a small volume change during the phase change. In addition, data available for thermo-physical properties of the Cu-Ge alloy is limited (Zhai et al, 2012). Similarly, there remains a dearth of information on the expected thermal response and consistence with the phase diagram based on the thermodynamic equilibrium, and favorable eutectic and liquefaction temperatures for TES in the net-generation CSP.…”

Phase Change Material of Copper–Germanium Alloy as Solar Latent Heat Storage at High Temperatures

“…The latent heat were estimated as 232.8, 198.2, and 163.5 kJ/kg for CuGe40, CuGe50, and CuGe60, respectively. The value of latent heat for CuGe40 is comparable to reference data (169.7 kJ/kg) (Zhai et al, 2012). Additionally, the heat storage density of CuGe50 increased in the temperature range 644-705°C owing to the latent heat from the primary Ge and sensible heat from the eutectic mixture, while the heat storage density of CuGe60 is enhanced in the temperature range 644-765°C.…”

“…There is a paucity of studies on the values of the specific heat (C p ) based on the temperature and thermophysical properties of the Cu-Ge alloy. The phase transition temperatures and enthalpy of fusion for Cu-Ge alloys with a wide range of chemical compositions have been examined (Zhai et al, 2012). In this study, the melting, solidification, and eutectic temperatures, enthalpies, and specific heat capacity of the alloys were measured using differential scanning calorimetry [DSC, NETZSCH DSC 404 F3 Pegasus ® manufactured by NETZSCH Co. Ltd., temperature resolution of ±0.0025 × |t|°C)] under an Ar flow of 100 ml/min with a heating and cooling rate of 10°C/min between room temperature and 900°C.…”

“…The latent heat were estimated as 41.8, 27.3, and 23.2 kJ/kg for CuGe40, CuGe50, and CuGe60, respectively. The value of latent heat for CuGe40 was estimated by reference data (28.4 kJ/kg) (Zhai et al, 2012). Strong discontinuous changes are the sum of sensible heat and latent heat released/stored in the solid/liquid phase transition (eutectic mixture of ε 2 + (Ge) 5 liquid phase) at a temperature of 644°C.…”

“…Si and Ge elements belong to the carbon group in the periodic table, in which the Cu-Ge alloy has a eutectic mixture containing Ge contents that may lead to a small volume change during the phase change. In addition, data available for thermo-physical properties of the Cu-Ge alloy is limited (Zhai et al, 2012). Similarly, there remains a dearth of information on the expected thermal response and consistence with the phase diagram based on the thermodynamic equilibrium, and favorable eutectic and liquefaction temperatures for TES in the net-generation CSP.…”

Phase Change Material of Copper–Germanium Alloy as Solar Latent Heat Storage at High Temperatures

“…If better calorimetric data are not available, the NKR is nowadays a standard method for constructing phase diagrams (e.g., within the CALPHAD approach) of multicomponent alloys, despite the fact that changes in the electronic structure due to the formation of compounds from the constituents are not taken into account. Besides its usual application to estimate heat capacities, equations similar to Equation ( 7 ) have also been applied to other thermodynamic quantities including the enthalpies of fusion [ 74 ], Gibbs free energy [ 75 ] and entropies of formations [ 76 ] of various compounds.…”

A Combined Experimental and First-Principles Based Assessment of Finite-Temperature Thermodynamic Properties of Intermetallic Al3Sc

Physical simulation of investment casting for GTD-222 Ni-based superalloy processed by controlled cooling rates