Talk:Ostwald–Freundlich equation

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"Gibbs-Thomson equation" used interchangeably with "Ostwald–Freundlich equation" in ALLAN S. MYERSON (Ed.); Handbook of industrial crystallization, Second Edition; Butterworth–Heinemann, Boston; 2002; 313 pp.

Comments?

— DIV (128.250.204.118 09:01, 12 March 2007 (UTC))[reply]

The usual version of the Gibbs-Thomson equation is different - see Melting-point depression and a page I have in preparation : User:Dr.BeauWebber/Gibbs-Thomson Equation / Effect - Kelvin equation is also different - but they are all related, and derived from / special cases of the generalised Gibbs Equations.

What are peoples views on if and how my page should be merged with this page ? Do we want to list the (many) permutations of the G-T equation, or just the main two variants for different applications (isolated particles / crystals in pores) ? cheers, Beau - Dr.BeauWebber (talk) 22:44, 21 February 2011 (UTC)[reply]

According to Lord Kelvin's equation of 1871,^[1][2]

${\displaystyle p(r_{1},r_{2})=P-{\frac {\gamma \,\rho \,_{vapor}}{(\rho \,_{liquid}-\rho \,_{vapor})}}\left({\frac {1}{r_{1}}}+{\frac {1}{r_{2}}}\right)}$

where

${\displaystyle p(r)}$ = vapor pressure at a curved interface of radius ${\displaystyle r}$

${\displaystyle P}$ = vapor pressure at flat interface (${\displaystyle r=\infty }$) = ${\displaystyle p_{eq}}$

${\displaystyle \gamma }$ = surface tension

${\displaystyle \rho \,_{vapor}}$ = density of vapor

${\displaystyle \rho \,_{liquid}}$ = density of liquid

${\displaystyle r_{1}}$ , ${\displaystyle r_{2}}$ = radii of curvature along the principal sections of the curved interface.

Note: Kelvin defined the surface tension ${\displaystyle \gamma }$ as the work that was performed per unit area by the interface rather than on the interface; hence the term containing ${\displaystyle \gamma }$ has a minus sign. In what follows, the surface tension will be defined so that the term containing ${\displaystyle \gamma }$ has a plus sign.

If the particle is assumed to be spherical, then ${\displaystyle r=r_{1}=r_{2}}$ .

Since ${\displaystyle \rho \,_{liquid}\gg \rho \,_{vapor}}$, then ${\displaystyle \rho \,_{liquid}-\rho \,_{vapor}\approx \rho \,_{liquid}}$.

Hence

${\displaystyle p(r)\approx P+{\frac {2\gamma \,\rho \,_{vapor}}{\rho \,_{liquid}\cdot r}}}$.

Assuming that the vapor obeys the ideal gas law, then

${\displaystyle \rho \,_{vapor}={\frac {m_{vapor}}{V}}={\frac {MW\cdot n}{V}}={\frac {MW\cdot P}{RT}}={\frac {MW\cdot P}{N_{0}k_{B}T}}}$

where

${\displaystyle m_{vapor}}$ = mass of a volume ${\displaystyle V}$ of vapor

${\displaystyle MW}$ = molecular weight of vapor

${\displaystyle n}$ = number of moles of vapor in volume ${\displaystyle V}$ of vapor

${\displaystyle R}$ = ideal gas constant = ${\displaystyle N_{0}k_{B}}$

${\displaystyle N_{0}}$ = Avogadro’s number

${\displaystyle k_{B}}$ = Boltzmann's constant

${\displaystyle T}$ = absolute temperature.

Since ${\displaystyle {\frac {MW}{N_{0}}}=}$ mass of one molecule of vapor or liquid, then

${\displaystyle {\frac {\left({\frac {MW}{N_{0}}}\right)}{\rho \,_{liquid}}}=}$ volume of one molecule ${\displaystyle =V_{molecule}}$ .

Hence

${\displaystyle p(r)\approx P+{\frac {2\gamma V_{molecule}P}{k_{B}Tr}}=P+{\frac {R_{critical}P}{r}}}$ ,

where ${\displaystyle R_{critical}={\frac {2\gamma V_{molecule}}{k_{B}T}}}$ .

Thus

${\displaystyle {\frac {p(r)-P}{P}}\approx {\frac {R_{critical}}{r}}}$ .

Since ${\displaystyle {\frac {p(r)}{P}}=1-{\frac {P-p(r)}{P}}}$ , then ${\displaystyle \log \left({\frac {p(r)}{P}}\right)=\log \left(1-{\frac {P-p(r)}{P}}\right)}$ .

Since ${\displaystyle p(r)\approx P}$, then ${\displaystyle {\frac {P-p(r)}{P}}\ll 1}$ .

If ${\displaystyle x\ll 1}$, then ${\displaystyle \log \left(1-x\right)\approx -x}$ .

Hence

${\displaystyle \log \left({\frac {p(r)}{P}}\right)\approx {\frac {p(r)-P}{P}}}$ .

Therefore

${\displaystyle \log \left({\frac {p(r)}{P}}\right)\approx {\frac {R_{critical}}{r}}}$ ,

which is the Ostwald-Freundlich equation.

Cwkmail (talk) 10:50, 20 February 2013 (UTC)[reply]

I have added this to the article. Arbitrarily0 ^(talk) 19:35, 9 January 2014 (UTC)[reply]