Stefan Ernst

Affiliations: 
Uniwersytet Śląski w Katowicach, Poland 
 1967 Uniwersytet Wroc?awski 
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"Stefan Ernst"
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Dzida M, Żak A, Ernst S. (2005) Thermodynamic and acoustic properties of binary mixtures of alcohols and alkanes. I. Speed of sound in (ethanol+ n -heptane) under elevated pressures The Journal of Chemical Thermodynamics. 37: 405-414
Dzida M, Ernst S. (2003) Speed of Sound in Propan-1-ol + Heptane Mixtures under Elevated Pressures Journal of Chemical and Engineering Data. 48: 1453-1457
Marczak W, Dzida M, Ernst S. (2000) Determination of the thermodynamic properties of 1-propanol and 1-hexanol from speed of sound measurements under elevated pressures High Temperatures-High Pressures. 32: 283-292
Żak A, Dzida M, Zorȩbski M, et al. (2000) A high pressure device for measurements of the speed of sound in liquids Review of Scientific Instruments. 71: 1756-1765
Ernst S, Chorążewski M, Tkaczyk M, et al. (2000) Heat capacities and densities of α,ω-dibromoalkanes as functions of temperature: A group additivity analysis Fluid Phase Equilibria. 174: 33-39
Ernst S, Gepert aM, Manikowski R. (1999) Apparent Molar Compressibilities of Aqueous Solutions of Cu(NO3)2, CuSO4, and CuCl2 from 288.15 K to 313.15 K Journal of Chemical & Engineering Data. 44: 1199-1203
Ernst S, Dzida M. (1998) Prediction of the speed of sound in the ethanol + n-heptane system. New application of the Extended Real Associated Solution model Fluid Phase Equilibria. 146: 25-33
Ernst S, Marczak aW, Kmiotek D. (1996) Ultrasonic velocity, density, and adiabatic compressibility for 2,6-dimethylpyridine + water in the temperature range 293-318 K Journal of Chemical & Engineering Data. 41: 128-132
Ernst S, Manikowski R, Bebek M. (1996) Measurements of the Speed of Sound and Density of Aqueous Solutions of the First-Row Transition Metal Halides. 3. Apparent Molar Compressibilities and Volumes of Aqueous CoI2 and NiI2 within the Temperature Range 291.15 K to 297.15 K Journal of Chemical & Engineering Data. 41: 397-401
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