Talk:Clausius-Clapeyron relation: Difference between revisions

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	To learn how to update the categories for this article, see here. To update categories, edit the metadata template.  Definition:  An equation that characterizes the phase transition between two phases of a single compound; the slope of the coexistence curve in the P-T diagram. [d] [e] Checklist and Archives  Workgroup category:  Chemistry [Please add or review categories]  Subgroup category:  Chemical Engineering  Talk Archive:  none  English language variant:  American English Unused subpages  Unused subpages:  - Bibliography - External Links - Works - Discography - Filmography - Catalogs - Timelines - Gallery - Audio - Video - Code - Tutorials - Student Level - Signed Articles - Function - Addendum - Debate Guide - Advanced - Recipes - Citable Version

Thanks for creating this article

I created two redirects to this article: Clausius-Clapeyron equation and Clausius-Clapeyron relation. Both redirects use the ordinary dash ( - ) on our keyboards. The difference between that and the dash that I think you used is ( - – ). Most readers will probably use the keyboard dash to search for this article. Anyhow, thanks for creating this article. Milton Beychok 17:33, 11 September 2009 (UTC)

Suggested revision of lead-in sentence

Paul, to me, a single-component is a single pure compound like say butane and liquids like gasoline or an aqueous solution of ethanol (which are mixtures of compounds) are not single-component systems. In the lead-in sentence, should it be revised to say "...an equation for a system consisting of two phases of matter in ..." rather than the current "...for a single-component system consisting of two phases in ..." ? Milton Beychok 15:50, 12 September 2009 (UTC)

Milt, I must confess that I don't have any hands-on experience with the C-C relation. But reading about it, I got the impression that it applies to single (pure) components only. At least the derivation is for pure systems, because it deals with only one chemical potential μ. It seems to me that for mixtures the proof must be extended with more μ's. Do you know anything about that?--Paul Wormer 16:16, 12 September 2009 (UTC)