{{Short description|Measure of the non-sphericity of molecules}}
The '''acentric factor''' {{math|ω}} is a conceptual number introduced by Kenneth Pitzer in 1955, proven to be useful in the description of fluids.<ref name=":0">{{cite web | url = https://www.e-education.psu.edu/png520/m8_p3.html | title = Acentric Factor and Corresponding States | access-date = 2013-11-06 | last = Adewumi | first = Michael | publisher = Pennsylvania State University}}</ref> It has become a standard for the phase characterization of single and pure components, along with other state description parameters such as molecular weight, critical temperature, critical pressure, and critical volume (or critical compressibility). The acentric factor is also said to be a measure of the non-sphericity (centricity) of molecules.<ref name=thermopedia>{{Cite book | last1 = Saville | first1 = G. | doi = 10.1615/AtoZ.a.acentric_factor | chapter = ACENTRIC FACTOR | title = A-to-Z Guide to Thermodynamics, Heat and Mass Transfer, and Fluids Engineering | year = 2006 }}</ref>
Pitzer defined {{math|ω}} from the relationship : <math>\omega = -\log_{10}(p^\text{sat}_\text{r}) - 1 \text{ at } T_\text{r} = 0.7,</math> where <math>p^\text{sat}_\text{r} = p^\text{sat} / p_c</math> is the reduced saturation vapor pressure, and <math>T_\text{r} = T / T_c</math> is the reduced temperature.<ref>{{Cite web |title=Acentric Factor Calculator |url=https://www.calculatoratoz.com/en/acentric-factor-calculator/Calc-29475 |access-date=2024-05-17 |website=www.calculatoratoz.com |language=en}}</ref>
Pitzer developed this factor by studying the vapor-pressure curves of various pure substances. Thermodynamically, the vapor-pressure curve for pure components can be mathematically described using the Clausius–Clapeyron equation.
The integrated form of equation is mainly used for obtaining vapor-pressure data mathematically. This integrated version shows that the relationship between the logarithm of vapor pressure and the reciprocal of absolute temperature is approximately linear.<ref name=":0" />
For a series of fluids, as the acentric factor increases the vapor curve is "pulled" down, resulting in higher boiling points. For many monatomic fluids, <math>p^\text{sat}_\text{r} \approx 0.1</math> at <math>T_\text{r} = 0.7,</math> which leads to <math>\omega \to 0</math>. In many cases, <math>T_\text{r} = 0.7</math> lies above the boiling temperature of liquids at atmosphere pressure.
Values of {{math|ω}} can be determined for any fluid from accurate experimental vapor-pressure data. The definition of {{math|ω}} gives values close to zero for the noble gases argon, krypton, and xenon. <math>\omega</math> is also very close to zero for molecules which are nearly spherical.<ref name="thermopedia" /> Values of {{math|ω ≤ −1}} correspond to vapor pressures above the critical pressure and are non-physical.
The acentric factor can be predicted analytically from some equations of state. For example, it can be easily shown from the above definition that a van der Waals fluid has an acentric factor of about −0.302024, which if applied to a real system would indicate a small, ultra-spherical molecule.<ref>{{cite journal |last1=Shamsundar |first1=N. |last2=Lienhard |first2=J. H. |title=Saturation and metastable properties of the van der waals fluid |journal=Canadian Journal of Chemical Engineering |date=December 1983 |volume=61 |issue=6 |pages=876–880 |doi=10.1002/cjce.5450610617 |url=https://onlinelibrary.wiley.com/doi/pdf/10.1002/cjce.5450610617 |access-date=10 August 2022|url-access=subscription }}</ref>
==Values of some common gases==
{| class="wikitable" ! Molecule ! Acentric factor<ref>{{cite book | title = Matheson Gas Data Book | last1 = Yaws | first1 = Carl L. | year = 2001 | publisher = McGraw-Hill }}</ref> |- | Acetone || {{0|−}}0.304<ref name="pgas4e">{{cite book |last1=Reid |first1=R. C. |last2=Prausnitz |first2=J. M. |last3=Poling |first3=B. E. |title=The Properties of Gases and Liquids |year=1987 |publisher=McGraw-Hill |isbn=0070517991 |edition=4th}}</ref> |- | Acetylene || {{0|−}}0.187 |- | Ammonia || {{0|−}}0.253 |- | Argon || {{0|−}}0.000 |- | Carbon dioxide || {{0|−}}0.228 |- | Decane || {{0|−}}0.484 |- | Ethanol || {{0|−}}0.644<ref name="pgas4e"/> |- | Helium || −0.390 |- | Hydrogen || −0.220 |- | Krypton || {{0|−}}0.000 |- | Methanol || {{0|−}}0.556<ref name="pgas4e"/> |- | Neon || {{0|−}}0.000 |- | Nitrogen || {{0|−}}0.040 |- | Nitrous oxide || {{0|−}}0.142 |- | Oxygen || {{0|−}}0.022 |- | Xenon || {{0|−}}0.000 |}
==See also==
* Equation of state * Reduced pressure * Reduced temperature
== References == <references/>
Category:Gas laws
{{thermodynamics-stub}}