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Since $K_c$ can already be used for calculating the equilibrium constant for a reaction involving gases, but $K_p$ cannot be used for calculating the equilibrium constant for a reaction involving aqueous solutions, what is the use for $K_p$?

It doesn't seem like there is ever a situation where $K_c$ cannot be used and $K_p$ must be used, especially since partial pressures can be readily converted to concentration through the ideal gas law. If anything, it just seems like the existence of two equilibrium constants that more often than not don't equal each other could cause more confusion.

Thoughts?

Gaurang Tandon
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Frank
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  • It's easier to use $\mathrm{K_p}$ rather than $\mathrm{K_c}$ in cases pertaining to gaseous equilibrium. – Avyansh Katiyar Apr 16 '18 at 06:40
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    https://chemistry.stackexchange.com/questions/40567/which-equilibrium-constant-is-appropriate-to-use highly descripted. – akgnitd Apr 16 '18 at 07:22
  • It depends on what units you use, if pressure is measured then use $K_p$, if concentration then $K_c=K_p(RT)^{-\Delta n}$ where $\Delta n$ is the change in the number of moles of gaseous substances as the reaction goes from left to right and $p$ is the total pressure. If mole fraction $K_x=K_pp^{-\Delta n}$. – porphyrin Apr 16 '18 at 07:31
  • @porphyrin isn't that just derived from the ideal gas law, like I mentioned in the question? – Frank Apr 16 '18 at 08:16
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    Ah... so it actually does make a difference. Thanks @akgnit. – Frank Apr 16 '18 at 08:16
  • @KarmanyaGB Sorry, this isn't a duplicate. That question asks whether the $K$ in $\Delta G^\circ = -RT \ln K$ stands for $K_p$ or $K_c$. This question does not even once mention that equation, and is in fact, a different question. – Gaurang Tandon Apr 16 '18 at 14:24
  • @GaurangTandon true, but that answers why the pressure equilibrium constant exists. Its the one that is correct (under certain assumptions) for gases and Kc would not work in that equation. – Tyberius Apr 16 '18 at 19:24

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