Acentric factor
The acentric factor ω is a conceptual number introduced by Kenneth Pitzer in 1955, proven to be very useful in the description of matter.[1] It has become a standard for the phase characterization of single & pure components. The other state description parameters are molecular weight, critical temperature, critical pressure, and critical volume (or critical compressibility). The acentric factor is said to be a measure of the non-sphericity (centricity) of molecules.[2] As it increases, the vapor curve is "pulled" down, resulting in higher boiling points.
It is defined as:
- .
where is the reduced temperature, is the reduced saturation vapor pressure.
For many monatomic fluids
- ,
is close to 0.1, therefore . In many cases, lies above the boiling temperature of liquids at atmosphere pressure.
Values of ω can be determined for any fluid from accurate experimental vapor pressure data. Preferably, these data should first be regressed against a vapor pressure equation, like ln(P) = A + B/T +C*ln(T) + D*T^6. (In this regression, a careful check for erroneous vapor pressure measurements must be made, preferably using a log(P) vs. 1/T graph, and any obviously incorrect or dubious values should be discarded. The regression should then be re-run with the remaining good values until a good fit is obtained.) Using the known critical temperature, Tc, vapor pressure at Tr=0.7 can then be used in the defining equation, above, to estimate acentric factor.
The definition of ω gives essentially zero for the noble gases argon, krypton, and xenon. is very close to zero for other spherical molecules.[2] Values of ω ≤ -1 correspond to vapor pressures above the critical pressure, and are non-physical.
By definition, a van der Waals fluid has a critical compressibility of 3/8 and an acentric factor of about −0.302024, indicating a small ultra-spherical molecule. A Redlich-Kwong fluid has a critical compressibility of 1/3 and an acentric factor of about 0.058280, close to nitrogen; without the temperature dependence of its attractive term, its acentric factor would be only -0.293572.
Values of some common gases
Molecule | Acentric Factor[3] |
Acetone | 0.304[4] |
Acetylene | 0.187 |
Ammonia | 0.253 |
Argon | 0.000 |
Carbon Dioxide | 0.228 |
Decane | 0.484 |
Ethanol | 0.644[4] |
Helium | -0.390 |
Hydrogen | -0.220 |
Krypton | 0.000 |
Methanol | 0.556[4] |
Neon | 0.000 |
Nitrogen | 0.040 |
Nitrous Oxide | 0.142 |
Oxygen | 0.022 |
Xenon | 0.000 |
See also
- Equation of state
- Reduced pressure
- Reduced temperature
References
- Adewumi, Michael. "Acentric Factor and Corresponding States". Pennsylvania State University. Retrieved 2013-11-06.
- Saville, G. (2006). "ACENTRIC FACTOR". A-to-Z Guide to Thermodynamics, Heat and Mass Transfer, and Fluids Engineering. doi:10.1615/AtoZ.a.acentric_factor.
- Yaws, Carl L. (2001). Matheson Gas Data Book. McGraw-Hill.
- Reid, R.C.; Prausnitz, J.M.; Poling, B.E. The Properties of Gases and Liquids (4th ed.). McGraw-Hill. ISBN 0070517991.