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Constant-Volume Heat Capacity of H2O + Na2CO3 Solutions Near the Critical Point of Pure Water

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The results of new isochoric heat capacity measurements of H2O + Na2CO3 solutions as a function of temperature along several isochores in the near-critical region of pure water are reported. The measurements cover temperatures from 331 to 661 K at Na2CO3 mole fraction 0.008869. The experiments were performed at seven densities between 245 and 875 kg-m−3. The measurements were made in a high-temperature, high-pressure, adiabatic, and nearly constant-volume calorimeter. Uncertainties of the isochoric heat capacity measurements are estimated to be 1–2% in the liquid phase, 2–3% in the vapor phase, and 4–5% near the critical point. Measurements were made in the two-phase (vapor–liquid, liquid–solid, vapor–solid) and three-phase (vapor–liquid–solid) regions. Two peaks in isochoric heat capacity have been found near the critical point of pure water. One of the peaks at T S1 occurs on the three-phase (L–V–S) curve and another peak at T S2 corresponds to a two-phase (L–S or V–S) curve. The experimental values of phase transition temperatures T S(ρ) on each isochore was determined. Uncertainty in the phase transition temperature measured was no greater than ±0.03 to 0.05 K.

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  1. Ilmutdin M. Abdulagatov, V. I. Dvoryanchikov, A. N. Kamalov & E. G. Abramova

    Present address: Center of the Russian Academy of Sciences, Institute for Geothermal Problems of the Dagestan Scientific, 367030, Makhachkala, Kalinina 39-A, Dagestan, Russia

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    1. Ilmutdin M. Abdulagatov
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    2. V. I. Dvoryanchikov
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    3. A. N. Kamalov
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    4. E. G. Abramova
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    Abdulagatov, I.M., Dvoryanchikov, V.I., Kamalov, A.N. et al. Constant-Volume Heat Capacity of H2O + Na2CO3 Solutions Near the Critical Point of Pure Water. Journal of Solution Chemistry 28, 865–883 (1999). https://doi.org/10.1023/A:1021784231509

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